Basic Principles of Forensic Chemistry
JaVed I. Khan • Thomas J. Kennedy Donnell R. Christian, Jr.
Basic Principles of Forensic Chemistry
JaVed I. Khan U.S. Crime Laboratory California Department of Justice Riverside, CA, USA
[email protected] Donnell R. Christian, Jr. Director of Forensic Programs Professional Business Solutions, Inc. 1000 Lake St. Louis Blvd, Suite 129 Lake St. Louis, MO, USA
[email protected] Thomas J. Kennedy Department of Chemistry Victor Valley Community College Victorville, CA, USA
[email protected] ISBN 978-1-934115-06-0 e-ISBN 978-1-59745-437-7 DOI 10.1007/978-1-59745-437-7 Springer New York Dordrecht Heidelberg London Library of Congress Control Number: 2011937225 © Springer Science+Business Media, LLC 2012 All rights reserved. This work may not be translated or copied in whole or in part without the written permission of the publisher (Humana Press, c/o Springer Science+Business Media, LLC, 233 Spring Street, New York, NY 10013, USA), except for brief excerpts in connection with reviews or scholarly analysis. Use in connection with any form of information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed is forbidden. The use in this publication of trade names, trademarks, service marks, and similar terms, even if they are not identified as such, is not to be taken as an expression of opinion as to whether or not they are subject to proprietary rights. Printed on acid-free paper Humana Press is part of Springer Science+Business Media (www.springer.com)
This book is dedicated to the students and teachers in the field of forensic sciences. JaVed I. Khan To my family: Tammy, Breanna, McKenna, and Holden. This work is dedicated to each of you for the sacrifices you have made. Thank you for enduring the long hours, you are my inspiration, and I love you all very much!! For my mother, Nancy, and my sister, Susan. Thank you for your love, guidance, and support for so many years. It is the foundation that drives me to be a better man. I love you. Thomas J. Kennedy To my parents and my wife Stephanie. Donnell R. Christian, Jr.
Foreword
Forensic chemistry was once the foundation of the crime laboratory. The modern forensic laboratory seems to be drifting away from its traditional roots, with the introduction of DNA evidence and the plethora of forensic shows on television. Emphasis in biology has replaced chemistry with serological and biological examinations. Degrees in forensic science have been created to address the demand created by the CSI culture. However, forensic chemistry remains the backbone of the modern forensic laboratory. I was once asked how I would council a person seeking a degree in forensic science. I reflected on the words of my mentor, my own personal experience with a degree in criminalistics, and the employment prospects for new graduates with a degree in forensic science as I formulated my response. I responded that I would advise them against seeking a degree in forensic science. Unfortunately, that was not the response the selection committee wanted to hear. This may seem an odd opening for a book foreword. However, the issues that factored into my response have been incorporated into this text. My mentor believed that he was not a science teacher. He would teach me how to apply the science I knew to the analysis of physical evidence. He was not going to waste his time teaching me things I should have learned in college. He was a brilliant man and could teach anyone to do the analysis, given enough time. He knew that it requires a scientist to understand how the analysis functions. He wanted to develop an examiner’s mind to be able to solve a problem, not train a technician to push buttons. A background in science is essential to work as a forensic examiner. The minimum requirement for most entry-level forensic laboratory positions is a degree in a hard or physical science. It was not until recently that forensic science was added to the list of accepted degrees. Additionally, a demonstrable minimum number of credit hours in chemistry and physics is required as part of the applicant’s course work. These requirements are in place to ensure that an entry-level person had a basic understanding of science to build a forensic scientist from. Finally, my degree is in criminalistics. In the early 1980s, no one knew what a criminalist or a forensic scientist was. Because a degree in chemistry was a requirement, every job application had a letter from the Chemistry Department Chairman stating that I had the equivalent course work to an ACS-certified degree in chemistry. This was in addition to a copy of my college transcripts. This rambling story does relate to Basic Principles of Forensic Chemistry. It has to do with the way the book is organized. Basic Principles of Forensic Chemistry is designed to develop the student’s understanding of forensic chemistry in a sequential manner. Basic chemistry principles are established. Generic examination techniques are presented followed by specific applications. Each section builds on the information developed in the previous sections. The focus of Basic Principles of Forensic Chemistry is on the analysis of controlled substances, specifically drugs of abuse. However, it provides all of the conceptual information used in any forensic chemistry section of a modern forensic laboratory. The science and the examination techniques discussed are as applicable to the analysis of drugs as they are to trace evidence. vii
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Specific reagents may change or sample preparation techniques may be modified, but the concepts are interchangeable. Part I lays the scientific foundation that the examiner needs to understand the science of analysis. The information in Part I reviews basic principles of chemistry beginning with atomic structure and expanding through molecules and into organic chemistry. The section is intended to be a review of chemistry basics, not a replacement for formal class work. Part II discusses the tools used by all examiners in the forensic chemistry section. Chapters 5 and 6 establish the terminology and paperwork flow common to all forensic chemistry sections. The following chapters discuss analytical techniques. Each chapter begins with generic theory and follows it with drug-analysis applications. Chapters 7 through 9 discuss the use of nonspecific tests and sample preparation techniques that are used as part of the screening process. Each section presents the basis for the examinations followed by sections of practical application. Chapters 10 and 11 address the instrumentation frequently used by drug chemists to confirm the identity of the controlled substance indicated by the screening process. The following Chaps. 8 and 9 are theoretical discussions on practical application. Additionally, the strengths and weaknesses of each instrument are addressed. Part III deals with the job at hand, specifically the different types of controlled substances encountered by forensic drug chemists. This section divides the controlled substances into generic categories based on structural similarities. Each chapter addresses the drugs most frequently encountered in the group under discussion. In turn, a brief history of topic drugs is provided along with pharmacological information and the analytical techniques used to identify them. Part IV concentrates on the most challenging portion of a forensic drug chemist’s job, clandestine laboratory operations. These operations force the forensic chemist out of the clinical analytical mindset. This type of analysis requires the chemist to utilize his knowledge of chemistry (Part I), combine it with analytical tools (Part II), and understand drugs of abuse (Part III). These examinations allow the drug chemist to use all the tools in his toolbox, along with deductive reasoning, to objectively examine and evaluate the data from evidence obtained from suspected clandestine drug labs. As you can see, Basic Principles of Forensic Chemistry is a process. A foundation of chemical knowledge supports an analytical scheme. The tools from the analytical toolbox are used to initially identify a generic class of drug followed by a specific compound identification. Finally, the chemist’s complete knowledge base and power of deductive reasoning are used to bring calm from the chaos of the evidence obtained from clandestine lab operations. Basic Principles of Forensic Chemistry will not turn the reader into a forensic chemist. However, it will provide the fundamental knowledge required to begin a very rewarding journey. Good luck on your journey. Chesterfield, VA
Donnell R. Christian, Jr.
Preface
I have not reinvented the wheel on forensic chemistry in this book. This book is merely an effort to consolidate previously developed, yet scattered, forensic chemistry-related information under one umbrella. I used all reliable resources that my predecessors and contemporary experts in the field of forensic chemistry have developed. For this reason, I consider myself an editor rather than an author of this book. The material presented is very basic and is not intended or recommended for legislative use. Primarily, this book is a milestone textbook toward teaching forensic chemistry at colleges and universities. Second, it is the first major, consolidated resource book for forensic laboratories throughout the country and overseas to train newly hired staff in controlled substance examination. I have developed a parallel laboratory manual with the book. The laboratory manual has 17 experiments that are exclusively designed to provide initial training to students and trainees of forensic chemistry. I also have developed an instructional PowerPoint presentation to assist instructors when teaching this course. This presentation is available to instructors at no extra cost. Unlike many other chemistry books, most of the questions at the end of each chapter in this book pertain to court testimony. The answers to these questions affect many lives positively or negatively. For this reason, I wanted the students of forensic chemistry to learn to answer court testimony-related questions. This book has room for improvement. I would like your suggestions, complaints, compliments, or concerns about the book. Please do not hesitate to drop me a line with suggestions for improvements to the future editions of this book.
Illustrations I have used many original illustrations in this book. I owe a special thanks to my forensic community at large for providing me hundreds of valuable original photos and illustrations for this book. If I ever requested one photo, I was given ten photos to choose from. Thank you once again. In addition, GCMS and FTIR instrument manufacturers such as Varian Instruments, Avatar (Nicolet) Instruments, HP Instruments, and Agilent Instruments have generously permitted the use of photos of their instruments for this book. Thank you all.
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I also used some photos from the public domain (citizen information centers) of US DOJ-DEA and other (forensic-related public domains) websites. Thank you for posting valuable photos on your websites for educational purposes. Microgram also permitted me to use illustrations. I am thankful to all of you for permitting the use your material for this book. This book would not be in its current form without your generous contributions. I always respected the copyrights and have avoided the use of any copyrighted material without permission in this book. Riverside, CA
JaVed I. Khan
Acknowledgments
Many selfless and silent individuals are behind a successful individual. Although I do not consider myself so successful, I do consider myself fortunate to be surrounded by the many silent, selfless, giving, and encouraging individuals of the forensic community. I owe a special thanks to the forensic community at large for their support and assistance from various angles. Your contributions have made this book very valuable and resourceful. California Department of Justice (CA-DOJ)–Division of Law Enforcement (DLE)–Bureau of Forensic Service (BFS) has invested and contributed in my professional growth and development for many years. Thank you. Joseph Rynearson and John DeHaan of the BFS are my role models. Both are the authors of well-read books in the field of forensic science. My mentor, the late Alfred Moses, was also a very inspiring soul. I thank the entire BFS staff for their support. Bureau chief Lance Gima and assistant chiefs Gill Spriggs and Eva Steinberger deserve my special thanks. My laboratory director, Gary Asbury, placed various encouraging posters all around the laboratory for me. My supervisor, Kristen Rager, provided me with unreserved support. Assistant laboratory directors Tom Nasser, Elisa Mayo, Steven Secofsky, Glen Owens, and Caroline Kim supported me as well. I thank Jerry Massetti of the California Criminalistic Institute (CCI) for his support and Waheed Jawadi of the CCI library for dispatching requested material in a timely manner. I thank my retired administrators Arthur Young, Mike White, Cecil Hider, and the late Jan Bashinsky. I thank my colleagues Hillary Bantrup, Anatoly Zolatoryov, Chantalle Clement, Brian Reinarz, Jennifer Dernoncourt, Bronwyn Weis, Gina Williams, and Larry Joiner for permitting the use of their photos in this book, and Bertha Castro, Cosette Larsen, Christina Ramirez, Alicia Lomas-Gross, David Wu, Marla Richardson, Michele Merritt, Rich Takanaga, Marianne Stam, Paul Sham, Lourdes Peterson, Phil Palez, Jim Hall, Kim Kreuz, Lynn Melgoza, Donna Merrill, John Bowden, Trina Duke-Robinson, Greg Crew, Frank Shagoya, Martin Romero, Tom Abercrombie, Terry Fickies, Tory Johnson, Bill Matty, and Theresa Anderson at Riverside Crime Laboratory for support and assistance. I learned much from all of my past and current colleagues. I thank my college colleagues Richard Collins, Lori Kildal, Camille Kraft, Richard Rowley, Pat Gummo, Angela Seavey, Richard LeGarra, E. Ozolin, Brianna Aliabdi, John Schuler, Nancy Politano, Jeff Splesky, Shelly Aguilar, and Randy Lim for support and assistance. I thank my co-authors T.J. Kennedy and D.R. Christian who helped me improve the overall outcome of this book. We made an awesome team. Thank you for believing in me. My parents would be proud of my efforts if they were alive. But I feel their prayers are with me forever.
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Best of all, my family members deserve the utmost credit and thanks. Knowing my life’s goals and ambitions, they never demanded any time from me. They, instead, created a calm home environment so I could work on the computer for hours without any disturbance or distraction. Thank you Fatima, Ahmed, and Sadia for unconditional support and love. Yes, I love you too. JaVed I. Khan My appreciation and respect to JaVed Khan for his leadership on this project. I would also like to thank those individuals who took time to contribute to this project. Thomas J. Kennedy I would like to thank Mr. Khan and Mr. Kennedy for the opportunity to participate in this project. I would also like to thank the people who researched the source documents used to reference this work. Donnell R. Christian, Jr.
Acknowledgments
About the Authors
Mr. Khan holds a master of science degree in biochemistry from the University of California, Riverside, a master of science degree in biochemistry from the University of Agriculture, Faisalabad, Pakistan, and a bachelor of science in chemistry/ biology from B.Z. University, Multan, Pakistan. He has more than 17 years of experience in the field of forensic sciences at the California State Department of Justice in the Riverside Crime Laboratory. He is an accomplished forensic scientist whose expertise expands in various fields, including forensic chemistry, forensic biology, and forensic toxicology. He has authored a number of publications on related topics. Mr. Khan responded to hundreds of clandestine laboratory JaVed I. Khan operations as a clandestine laboratory field expert. He examined the evidence from thousands of clandestine laboratory operations. Mr. Khan testified in various courts as a clandestine laboratory analyses expert witness. Mr. Khan is a recognized expert witness in other fields of forensics and has appeared more than 300 times in federal, state, and local county courts in this capacity. Mr. Khan has more than 12 years of teaching experience as a part-time college instructor of forensic chemistry and biology. He has developed curriculum of forensic chemistry, forensic biology, and forensic toxicology courses for Mt. San Jacinto College in Riverside, California. He is a dedicated professional whose insight and tireless efforts provided the driving force for this project.
Mr. Kennedy holds a bachelor of science degree in chemistry from the University of Rochester, Rochester, NY and a master of science degree in chemistry from California State Polytechnic University, Pomona, CA. Mr. Kennedy is a former police officer and has been teaching chemistry at Victor Valley College since 1994. He has been chairman of the Department of Chemistry for the past eight years. Mr. Kennedy is a passionate teacher focused on student success. Thomas J. Kennedy
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Donnell R. Christian is a PhD candidate at the University of South Africa, holds a Masters in Criminal Justice from American Military University and Bachelor’s degrees in Chemistry and Police Administration from Northern Arizona University. He is the author of Forensic Investigation of Clandestine Laboratories (2003). His companion book, Field Guide to Clandestine Laboratory Identification and Investigation (2004), provides a ready reference for police, fire, and emergency responders who potentially encounter clandestine labs in their daily activities. Mr. Christian has published articles on the analysis, and the clandestine manufacture and analysis, of controlled substances and has developed training programs for investigators, laboratory examDonnell R. Christian iners, and attorneys involved in the investigation, examination, and prosecution of clandestine labs. He also authored a chapter concerning the analysis of controlled substances in Forensic Science, An Introduction to Scientific and Investigative Techniques (2002, 2005, 2009) and the forensic chemistry section in The Forensic Laboratory Handbook, Procedures and Practices (2005, 2011). Mr. Christian is the director of Forensic Programs at Professional Business Solutions, Inc., and is the former Forensic Science Development Coordinator for the United States Department of Justice’s International Criminal Investigative Training Assistance Program (ICITAP). With ICITAP, he has assisted in establishing forensic science programs in the developing democracies of Armenia, Azerbaijan, Bosnia, Bulgaria, Georgia, Haiti, Kazakhstan, Kyrgyzstan, Senegal, Turkmenistan, and Uzbekistan. Mr. Christian served as president and chairman of the Board of Directors for the Southwestern Association of Forensic Scientists (SWAFS). Additionally, he spent 15 years with the Arizona Department of Public Safety Crime Laboratory specializing in forensic chemistry and trace analysis, with emphasis in the clandestine manufacture of controlled substances (i.e., drugs and explosives). He has responded to hundreds of clandestine lab scenes, examined thousands of exhibits, and provided untold hours of testimony.
About the Authors
Contents
Part I
Introduction to Forensic Chemistry
1
Introduction .............................................................................................................. 1.1 Forensic Chemistry ......................................................................................... 1.2 Scientific Investigation .................................................................................... 1.3 Forensic Investigation ..................................................................................... 1.4 Properties of Matter ........................................................................................ 1.5 Physical Properties .......................................................................................... 1.6 Chemical Properties ........................................................................................ 1.7 Questions.........................................................................................................
3 3 4 4 5 5 6 7
2
Atomic Structure ...................................................................................................... 2.1 Introduction ..................................................................................................... 2.2 Periodic Table ................................................................................................. 2.3 Atomic Structure ............................................................................................. 2.4 Subatomic Particles ......................................................................................... 2.5 The Arrangement of Electrons in an Atom ..................................................... 2.6 Electron Configurations .................................................................................. 2.7 Periodic Trends: Understanding the Periodic Table........................................ 2.8 Isotopes ........................................................................................................... 2.9 Radioactivity ................................................................................................... 2.10 Types of Radioactive Decay............................................................................ 2.11 Nuclear Radiation: Forensic Applications ...................................................... 2.12 The Mole and Molar Mass .............................................................................. 2.13 Elements of Forensic Interest.......................................................................... 2.14 Questions......................................................................................................... Suggested Reading .....................................................................................................
9 9 9 10 11 12 13 17 18 18 19 19 20 20 20 21
3
Molecules .................................................................................................................. 3.1 Introduction ....................................................................................................... 3.2 Chemical Bonding ............................................................................................ 3.2.1 Ionic Bonds ......................................................................................... 3.2.2 Covalent Bonds ................................................................................... 3.2.3 Polar Bonds ......................................................................................... 3.2.4 Hydrogen Bonding .............................................................................. 3.2.5 Multiple Bonds.................................................................................... 3.3 Predicting Bond Types ...................................................................................... 3.3.1 Nonpolar Covalent Bonds ................................................................... 3.3.2 Polar Covalent Bonds ..........................................................................
23 23 23 23 24 25 26 26 27 27 27
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3.3.3 Hydrogen Bonds ................................................................................. 3.3.4 Ionic Bonds ......................................................................................... Molar Mass ....................................................................................................... Molarity............................................................................................................. Chemical Reactions .......................................................................................... Questions...........................................................................................................
27 27 27 28 28 29
Organic Chemistry................................................................................................... 4.1 Introduction ..................................................................................................... 4.2 Classification of Organic Compounds: Functional Groups ............................ 4.2.1 Alkanes ............................................................................................. 4.2.2 Alkenes ............................................................................................. 4.2.3 Alkynes ............................................................................................. 4.2.4 Aromatic Compounds ....................................................................... 4.2.5 Alcohols ............................................................................................ 4.2.6 Ketones ............................................................................................. 4.2.7 Aldehydes ......................................................................................... 4.2.8 Carboxylic Acids .............................................................................. 4.2.9 Esters................................................................................................. 4.2.10 Nitro Compounds.............................................................................. 4.2.11 Amines .............................................................................................. 4.3 Methyl Group (–CH3) ..................................................................................... 4.4 Compounds Containing Multiple Functional Groups ..................................... 4.5 Chirality .......................................................................................................... 4.6 Questions......................................................................................................... Suggested Reading .....................................................................................................
31 31 31 32 37 39 40 41 44 46 47 49 50 51 54 54 55 56 57
3.4 3.5 3.6 3.7 4
Part II 5
Tools of Forensic Chemistry
Forensic Language .................................................................................................. 5.1 Defining Drugs ................................................................................................ 5.2 Origin of Drugs (Narcotics) ............................................................................ 5.2.1 Natural Drugs ...................................................................................... 5.2.2 Synthetic Drugs ................................................................................... 5.2.3 Psychotropic Drugs (Mind Altering) .................................................. 5.3 Dependence and Addiction ............................................................................. 5.3.1 Physical Dependence .......................................................................... 5.3.2 Psychological Dependence ................................................................. 5.4 Drug Abuse ..................................................................................................... 5.5 Hazards of Drug Abuse ................................................................................... 5.6 Structural Relationships .................................................................................. 5.6.1 Analogs ............................................................................................... 5.6.2 Designer Drugs ................................................................................... 5.6.3 Isomers ................................................................................................ 5.7 Controlled Substance Statutes......................................................................... 5.7.1 Controlled Substances Act .................................................................. 5.7.2 Controlled Substances Laws ............................................................... 5.7.3 Controlled Substance: Charges and Offenses ..................................... 5.8 Controlled Substance Submission to Crime Laboratories .............................. 5.9 Drug Cases in Crime Laboratories .................................................................. 5.10 Examination of Controlled Substances ........................................................... 5.11 Usable Quantity .............................................................................................. 5.12 Court Testimony.............................................................................................. 5.13 Qualifications and Education .......................................................................... 5.14 Questions......................................................................................................... Suggested Reading .....................................................................................................
61 61 61 61 61 61 62 62 62 63 63 64 64 64 65 66 66 66 67 67 68 69 69 69 69 70 70
Contents
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6
Forensic Documentation .......................................................................................... 6.1 Introduction ..................................................................................................... 6.2 Chain of Custody ............................................................................................ 6.3 Case Notes ...................................................................................................... 6.3.1 Types ................................................................................................... 6.3.2 Purpose ................................................................................................ 6.3.3 Content ................................................................................................ 6.3.4 Format ................................................................................................. 6.3.5 Dissemination...................................................................................... 6.4 Case Report ..................................................................................................... 6.4.1 Purpose ................................................................................................ 6.4.2 Format and Content ............................................................................. 6.5 Examples ......................................................................................................... 6.5.1 Example One ....................................................................................... 6.5.2 Example Two ...................................................................................... 6.6 Questions......................................................................................................... Suggested Reading .....................................................................................................
71 71 71 72 72 74 74 75 75 75 75 75 76 76 76 76 77
7
Chemical Screening.................................................................................................. 7.1 Introduction ..................................................................................................... 7.2 Chemistry of Color Formation ........................................................................ 7.3 Limitations of Chemical Color Tests .............................................................. 7.4 Chemical Color-Test Methods ........................................................................ 7.5 Documentation ................................................................................................ 7.6 Chemical Color Tests ...................................................................................... 7.6.1 Chen’s Test........................................................................................ 7.6.2 Dille–Koppanyi’s Test ...................................................................... 7.6.3 Mecke’s Test ..................................................................................... 7.6.4 Marquis’ Test .................................................................................... 7.6.5 Nitric Acid Test................................................................................. 7.6.6 Primary Amine Test .......................................................................... 7.6.7 Secondary Amine Test ...................................................................... 7.6.8 Tertiary Amine Test .......................................................................... 7.6.9 Van-Urk’s Test .................................................................................. 7.6.10 Duquenois–Levine Test .................................................................... 7.6.11 Froehde’s Test ................................................................................... 7.6.12 Janovsky Test .................................................................................... 7.6.13 Weber Test ........................................................................................ 7.7 Summary of Chemical Color Tests ................................................................. 7.8 Questions......................................................................................................... Suggested Reading .....................................................................................................
79 79 79 81 81 82 82 82 83 83 84 85 86 86 86 86 87 87 87 88 88 90 90
8
Microcrystal Techniques ......................................................................................... 8.1 Introduction ....................................................................................................... 8.2 Advantages of Microcrystal Techniques ........................................................... 8.3 Disadvantages of Microcrystal Techniques ...................................................... 8.4 Documentation .................................................................................................. 8.5 Microcrystal Test Techniques ........................................................................... 8.5.1 Aqueous Test Technique ..................................................................... 8.5.2 Volatility Test Technique..................................................................... 8.5.3 Acid and Anionic Test Technique ....................................................... 8.6 Aqueous Test Reagents ..................................................................................... 8.6.1 Gold Chloride Test .............................................................................. 8.6.2 Gold Chloride in Phosphoric Acid Test .............................................. 8.6.3 Platinum Chloride Test........................................................................
91 91 91 92 92 94 94 95 95 95 95 95 96
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8.6.4 Mercuric Iodide Test ........................................................................... 8.6.5 Mercuric Chloride Test ....................................................................... 8.6.6 Potassium Permanganate Test ............................................................. 8.6.7 Sodium Acetate Test ........................................................................... 8.7 Critical Considerations.................................................................................... 8.8 Questions......................................................................................................... Suggested Reading .....................................................................................................
96 96 96 96 96 97 97
9
Chemical Extractions and Sample Preparation .................................................... 9.1 Introduction ..................................................................................................... 9.2 Techniques ...................................................................................................... 9.2.1 Solid–Liquid Extraction ...................................................................... 9.2.2 Liquid–Liquid Extraction .................................................................... 9.2.3 Acid–Base Extraction .......................................................................... 9.2.4 Neutral Compound Extraction ............................................................. 9.3 Sample Preparation ......................................................................................... 9.4 Gas Chromatography/Gas Chromatography Mass Spectrometry ................... 9.5 Dry-Extraction Gas-Chromatography Modification ....................................... 9.6 Acid–Base-Extraction Gas-Chromatography Modification ............................ 9.7 Infrared Spectroscopy ..................................................................................... 9.8 Acid–Base-Extraction Infrared-Modification-I .............................................. 9.9 Acid–Base-Extraction Infrared-Modification-II ............................................. 9.10 Methanol Extraction........................................................................................ 9.11 Questions......................................................................................................... Selected Reading........................................................................................................
99 99 99 99 100 101 102 103 103 104 104 104 105 105 105 106 106
10
Chromatography and Mass Spectrometry ............................................................ 10.1 Introduction ..................................................................................................... 10.2 Chromatographic Techniques ......................................................................... 10.2.1 Paper Chromatography ...................................................................... 10.2.2 Thin-Layer Chromatography ............................................................. 10.2.3 Column Chromatography .................................................................. 10.2.4 Ion-Exchange Chromatography......................................................... 10.2.5 High-Performance Liquid Chromatography...................................... 10.2.6 Gas Chromatography ......................................................................... 10.2.7 Chromatography: Limitations ........................................................... 10.2.8 Interpretation of GC Chromatograms ................................................ 10.3 Mass Spectrometry.......................................................................................... 10.3.1 Ionization ........................................................................................... 10.3.2 Electron Impact ................................................................................. 10.3.3 Chemical Ionization........................................................................... 10.3.4 Mass Spectral Fragmentation ............................................................ 10.3.5 Mass Analyzers (Filters).................................................................... 10.3.6 Quadrupole Mass Analyzers.............................................................. 10.3.7 Magnetic Sector Mass Analyzers ...................................................... 10.3.8 Ion Trap Mass Analyzers ................................................................... 10.4 Advantages of Gas Chromatography Mass Spectrometry .............................. 10.5 Disadvantages of Gas Chromatography Mass Spectrometry .......................... 10.6 Questions......................................................................................................... Suggested Reading .....................................................................................................
107 107 107 107 109 110 110 111 112 115 115 116 117 117 118 118 119 119 123 123 124 124 125 125
11
Infrared Spectroscopy ............................................................................................. 11.1 Introduction ..................................................................................................... 11.2 Theory of Infrared Spectroscopy .................................................................... 11.3 Infrared Spectrum ...........................................................................................
127 127 127 129
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11.4
Instrumentation ............................................................................................. 11.4.1 Dispersive Infrared Spectrometer.................................................... 11.4.2 Spectrometer Components .............................................................. 11.4.3 Spectrometer Design ....................................................................... 11.4.4 Limitations of Dispersive Infrared .................................................. 11.5 Fourier Transform Infrared Spectrometer ...................................................... 11.5.1 Spectrometer Components .............................................................. 11.5.2 Spectrometer Design ....................................................................... 11.5.3 Advantages of Fourier Transform Infrared Spectrometers ............. 11.5.4 Fourier Transform Infrared Sample Preparation Techniques .......... 11.6 Sampling Techniques .................................................................................... 11.6.1 Nujol Mull ....................................................................................... 11.6.2 Cast Film A ..................................................................................... 11.6.3 Cast Film B ..................................................................................... 11.6.4 Pellets .............................................................................................. 11.6.5 Synthetic Membrane Sample Cards ................................................ 11.7 Reflectance .................................................................................................... 11.8 Fourier Transform Infrared Spectroscopy ..................................................... 11.9 Advantages of Fourier Transform Infrared Spectroscopy............................. 11.10 Disadvantages of Fourier Transform Infrared Spectroscopy ........................ 11.11 Instrument Selection for Forensic Identification........................................... 11.12 Inorganic Analysis ........................................................................................ 11.13 Organic Analysis ........................................................................................... 11.14 Questions....................................................................................................... Suggested Reading ..................................................................................................... Part III
129 129 129 131 132 132 133 133 134 134 136 136 136 136 136 137 137 137 137 137 137 138 139 141 141
Examination of Drugs/Narcotics
12
Cannabis ................................................................................................................... 12.1 Introduction ..................................................................................................... 12.2 History............................................................................................................. 12.3 Packaging for Forensic Examination .............................................................. 12.4 Forms of Cannabis .......................................................................................... 12.5 Psychoactive Ingredient .................................................................................. 12.6 Forensic Identification of Marijuana ............................................................... 12.6.1 Botanical Identification ..................................................................... 12.6.2 Macroscopic Properties ..................................................................... 12.6.3 Microscopic Identification ................................................................. 12.6.4 Chemical Identification (Duquenois–Levine Test) ............................ 12.6.5 Thin-Layer Chromatography ............................................................. 12.6.6 Gas Chromatography Mass Spectrometry ......................................... 12.7 Documentation ................................................................................................ 12.8 Questions......................................................................................................... Suggested Reading .....................................................................................................
145 145 145 147 147 147 149 149 149 151 151 153 154 154 156 156
13
Phenethylamines ...................................................................................................... 13.1 Introduction ..................................................................................................... 13.2 Methyl Derivatives .......................................................................................... 13.2.1 Amphetamine .................................................................................... 13.2.2 Methamphetamine ............................................................................. 13.2.3 Phentermine ....................................................................................... 13.3 Hydroxyl Derivatives ...................................................................................... 13.3.1 Phenylpropanolamine ........................................................................ 13.3.2 Ephedrine/Pseudoephedrine .............................................................. 13.3.3 Ephedra Plant: Introduction and History ...........................................
157 157 157 158 159 161 162 162 163 164
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13.4
Ketone Derivatives .......................................................................................... 13.4.1 Cathinone ........................................................................................... 13.4.2 Methcathinone ................................................................................... 13.4.3 Khat ................................................................................................... 13.5 Methylenedioxy Derivatives ........................................................................... 13.5.1 3,4-Methylenedioxyamphetamine ..................................................... 13.5.2 3,4-Methylenedioxymethamphetamine ............................................. 13.6 Methoxy Derivatives ....................................................................................... 13.6.1 Mescaline ........................................................................................... 13.7 Analytical Methods ......................................................................................... 13.7.1 Visual Inspection ............................................................................... 13.7.2 Chemical Screening ........................................................................... 13.7.3 Microcrystal Tests.............................................................................. 13.7.4 Extraction Techniques ....................................................................... 13.7.5 Extraction of Mescaline from Peyote ................................................ 13.7.6 Confirmatory Examination ................................................................ 13.8 Questions......................................................................................................... Suggested Reading .....................................................................................................
164 164 165 165 166 167 167 168 168 170 170 170 170 171 172 172 175 175
14
Tertiary Amines........................................................................................................ 14.1 Introduction ..................................................................................................... 14.2 Natural Tertiary Amines .................................................................................. 14.2.1 Cocaine .............................................................................................. 14.2.2 Opiates ............................................................................................... 14.3 Synthetic Tertiary Amines............................................................................... 14.3.1 Phenylcyclohexylpiperidine .............................................................. 14.4 Analytical Methods ......................................................................................... 14.4.1 Visual Inspections .............................................................................. 14.4.2 Chemical Screening of Tertiary Amines ........................................... 14.4.3 Confirmatory Examination ................................................................ 14.5 Questions ......................................................................................................... Suggested Reading .....................................................................................................
177 177 177 177 179 182 182 183 183 183 185 190 190
15
Tryptamines .............................................................................................................. 15.1 Introduction ..................................................................................................... 15.2 Natural Tryptamines ....................................................................................... 15.2.1 Psilocin and Psilocybin (Psychoactive Mushrooms) ......................... 15.2.2 Bufotenin ........................................................................................... 15.2.3 Methoxy Derivatives.......................................................................... 15.3 Synthetic Tryptamines .................................................................................... 15.4 Analytical Methods ......................................................................................... 15.4.1 Visual Identification........................................................................... 15.4.2 Chemical Screening Tests.................................................................. 15.4.3 Extraction of Psilocin and Psilocybin from Mushrooms ................... 15.4.4 Thin-Layer Chromatography ............................................................. 15.4.5 Gas-Chromatography Mass Spectrometry......................................... 15.5 Questions......................................................................................................... Suggested Reading .....................................................................................................
191 191 192 192 193 195 197 197 197 198 199 199 199 205 206
16
Anabolic Steroids ..................................................................................................... 16.1 Introduction and History ................................................................................. 16.2 Naturally Occurring Steroid Hormones .......................................................... 16.3 Anabolic Steroids ............................................................................................ 16.3.1 General Structure ............................................................................... 16.3.2 Physical and Psychological Effects ...................................................
207 207 208 210 210 211
Contents
xxi
17
16.3.3 Methods of Administration................................................................ 16.3.4 Nomenclature of Anabolic Steroids .................................................. 16.3.5 Frequently Encountered Steroids ...................................................... 16.4 Analytical Methods ......................................................................................... 16.4.1 Visual Inspections .............................................................................. 16.4.2 Gas Chromatography Mass Spectrometry ......................................... 16.4.3 Mass Spectra of Commonly Encountered Steroids ........................... 16.5 Questions......................................................................................................... Suggested Reading .....................................................................................................
211 211 212 213 213 213 214 222 222
Miscellaneous Controlled Substances .................................................................... 17.1 Introduction ..................................................................................................... 17.2 Barbiturates ..................................................................................................... 17.3 Fentanyl........................................................................................................... 17.4 Gamma-Hydroxybutyric Acid: g-Hydroxybutyric Acid ................................. 17.5 Ketamine ......................................................................................................... 17.6 Lysergic Acid Diethylamide ........................................................................... 17.7 Analytical Methods ......................................................................................... 17.7.1 Visual Identification........................................................................... 17.7.2 Chemical Screening Tests.................................................................. 17.7.3 Gas-Chromatography Mass Spectrometry......................................... 17.8 Questions......................................................................................................... Suggested Reading .....................................................................................................
223 223 223 225 226 227 228 229 229 230 230 237 237
Part IV
Clandestine Laboratory Operations
18
Clandestine Operations: Synthetic Methods, Hazards, and Safety ............... 18.1 Introduction ..................................................................................................... 18.2 Clandestine Operations ................................................................................... 18.2.1 Synthesis of Cocaine ......................................................................... 18.2.2 Synthesis of Fentanyl......................................................................... 18.2.3 Synthesis of g-Hydroxybutyric Acid ................................................. 18.2.4 Synthesis of Heroin ........................................................................... 18.2.5 Synthesis of Lysergic Acid Diethylamide ......................................... 18.2.6 Synthesis of 3,4-Methylenedioxymethamphetamine ........................ 18.2.7 Synthesis of Methcathinone .............................................................. 18.2.8 Synthesis of Phencyclidine ................................................................ 18.2.9 Synthesis of N,N-Dimethyltryptamine .............................................. 18.3 Synthesis of Methamphetamine: The Clandestine Operation of Choice ........ 18.3.1 Cold Method ...................................................................................... 18.3.2 Hot Method ........................................................................................ 18.4 Potential Hazards Associated with Clandestine Operations ........................... 18.5 Safety Considerations ..................................................................................... 18.6 Role of the Forensic Chemist at Clandestine Lab Sites .................................. 18.6.1 Advisory ............................................................................................ 18.6.2 Evidence Collection........................................................................... 18.7 Questions......................................................................................................... Suggested Reading .....................................................................................................
241 241 241 241 242 242 244 245 246 247 248 248 249 249 251 253 253 253 254 254 254 254
19
Evidence Identification and Collection .................................................................. 19.1 Clandestine Operations: A Forensic Analogy................................................. 19.2 Signs of Clandestine Operations ..................................................................... 19.3 Identification of Related Evidence .................................................................. 19.4 Solutions Frequently Encountered at Clandestine Sites .................................
257 257 257 258 260
xxii
Contents
19.5
Clandestine Production of Methamphetamine ................................................ 19.5.1 Extraction of Pseudoephedrine from Cold Tablets (Step I) ............... 19.5.2 Manufacturing of Methamphetamine (Step II).................................. 19.5.3 Processing of Methamphetamine (Step III) ....................................... 19.5.4 Icing of Methamphetamine (Step IV)................................................ 19.6 Collection of Evidence.................................................................................... 19.7 Collection of Washes ...................................................................................... 19.8 Questions......................................................................................................... Suggested Reading .....................................................................................................
261 261 262 263 263 263 266 267 267
Examination of Clandestine Evidence ................................................................... 20.1 Introduction ..................................................................................................... 20.2 Examination of Evidence to Prove Extraction (Step I) .................................. 20.2.1 Evidence Type ................................................................................... 20.2.2 Examination ....................................................................................... 20.3 Examination of Evidence to Prove Manufacturing of Methamphetamine (Step II) .......................................................... 20.3.1 Evidence Type ................................................................................... 20.3.2 Examination ....................................................................................... 20.3.3 Confirmatory Examination ................................................................ 20.4 Examination of Evidence to Prove Processing of Methamphetamine (Step III) ...................................................................... 20.4.1 Evidence Type ................................................................................... 20.4.2 Examination of Biphasic Solutions ................................................... 20.5 Examination of Evidence to Prove Icing (Step IV) ........................................ 20.6 Examination of Stains ..................................................................................... 20.7 Examination of Washes................................................................................... 20.8 Determining Methods of Methamphetamine Production ............................... 20.9 Questions......................................................................................................... Suggested Reading .....................................................................................................
269 269 269 269 270
Laboratory Manual ......................................................................................................... Experiment # 2 ........................................................................................................... Experiment # 3 ........................................................................................................... Experiment # 4 ........................................................................................................... Experiment # 5 ........................................................................................................... Experiment # 6 ........................................................................................................... Experiment # 7 ........................................................................................................... Experiment # 8 ........................................................................................................... Experiment # 9 ........................................................................................................... Experiment # 10 ......................................................................................................... Experiment # 11 ......................................................................................................... Experiment # 12 ......................................................................................................... Experiment # 13 ......................................................................................................... Experiment # 14 ......................................................................................................... Experiment # 15 ......................................................................................................... Experiment # 16 ......................................................................................................... Experiment # 17 ......................................................................................................... Experiment # 18 ......................................................................................................... Experiment # 19 ......................................................................................................... Experiment # 20 .........................................................................................................
283 286 288 290 292 298 300 304 310 312 314 316 320 323 325 328 332 335 338 341
20
270 270 271 274 274 274 275 275 277 278 279 282 282
Index .................................................................................................................................. 345
Part I Introduction to Forensic Chemistry
1
Introduction
1.1
Forensic Chemistry
Forensic science is the application of scientific principles to matters involving the law. This area of science is generally considered quite fascinating and it continues to experience growing popularity. Many would agree that the current public interest in forensics is a direct result of CSI-related television programming. These weekly shows have brought a once relatively unknown area of science to the forefront of public mainstream. Viewers are captivated and intrigued by well-informed scientists working in spotless labs with ominous lighting and a modern music background. The use of cutting-edge technology provides last-minute revelations culminating in the solution of a complex crime. These programs are entertaining and have certainly increased public awareness to the field of forensics; but alas, television is not reality. Although it is true that forensic science has experienced tremendous growth, few would (or should) believe this to be the result of fictional television programming. Media coverage of high-profile cases has increased over the last decade in both numbers and content. Crime-scene investigation and forensic analysis have been brought out of the lab and into the public’s “scrutinizing eye.” Forensic science, once a broad field, has become segregated into highly specialized disciplines. For example, forensic chemistry, forensic pathology, forensic dentistry, forensic entomology, and forensic DNA analysis have evolved into independent fields of forensics. It seems more appropriate – and clearly more realistic – to attribute the unprecedented popularity of forensic investigation to enhanced public awareness and an increase in the availability of career opportunities. Chemistry is the study of the composition of matter and the changes it undergoes. Forensic chemistry is a specialized area of forensic science involving the application of chemical principles and techniques to the field of forensic investigation. The role of forensic chemistry in criminal investigations is vast and ranges from techniques used to collect and preserve evidence, to complex chemical procedures used to identify elements and compounds. Identification procedures are highly reliable and are frequently based on the chemical and physical properties of the substance supported by data obtained from analytical analysis. Most chemical techniques used for isolation, purification, and identification are valid forensic techniques; however, chemical analysis differs from forensic chemical analysis in two ways: regulatory and judiciary. The results of forensic investigation may have a serious impact on lives. Therefore, techniques performed during forensic analysis must be closely regulated to ensure the accuracy and integrity of experimental results. Forensic laboratories must develop two operating manuals designed to meet the specific needs of each laboratory. The technical procedures manual outlines the step-by-step details of all procedures used in forensic examinations. The quality-control manual is designed to maintain the highest standards of reliability and integrity of work done by scientists in the lab. Adherence to both the technical procedures manual and lab quality manual is a crucial part of any analysis and is strictly enforced both internally and externally. Internal quality control includes, but is not limited to, periodic instrument calibration, checking reagents for expiration, and performance evaluations on scientists working in the laboratory. In addition, a detailed record is kept of all internal quality procedures performed. Outside regulatory agencies are responsible for external quality control and these agencies may vary from state to state in the US. The American Society of Crime Laboratory Directors (ASCLD) has recently accepted the painstaking task of regulating various fields within forensic science worldwide. This includes the forensic chemistry section in the United States. ASCLD is the regulatory organization responsible for supervising, evaluating, and directing all laboratories within its membership. Their designated inspectors evaluate technical staff and conduct periodic site inspections to ensure the highest standards of quality and technical performance. The efforts of ASCLD have helped to streamline and
J.I. Khan et al., Basic Principles of Forensic Chemistry, DOI 10.1007/978-1-59745-437-7_1, © Springer Science+Business Media, LLC 2012
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1
Introduction
standardize forensic analytical techniques worldwide. In addition, ASCLD provides direction and qualified solutions to potential issues facing member laboratories. Courtroom presentation of scientific principles and techniques used during forensic examination is the judiciary responsibility of the forensic chemist. Forensic chemists are often called upon to describe complex chemical procedures to individuals who have a limited understanding of scientific principles. This responsibility can present a variety of challenges to the forensic chemist as an expert witness. Courtroom testimony is carefully prepared using common terminology and the presentation must be in a clear, simple manner that avoids confusion and misinterpretation. To achieve this, forensic chemists often use common analogies to describe complex chemical and analytical techniques. For example, a gas chromatograph is an instrument used to separate a gaseous mixture into individual components based on size and/or charge. The description of how a gas chromatograph functions may contain a reference to coin-separating machines frequently found in local grocery stores. A coin machine separates the mixture of coins based on size, and totals each pile based on weights. This analogy would illustrate how a gas chromatograph functions and may help members of a jury be more comfortable with testimony about this complex instrument. Similar analogies will be used in the following chapters to describe complex chemical procedures and analytical techniques frequently used in forensic chemistry. These analogies are designed to promote an understanding of the topic under discussion while adding clarity and continuity to the subject.
1.2
Scientific Investigation
Imagine yourself in a classroom for an extended period of time without the ability to see outside. When you exit the building, you immediately notice that the ground is wet. Your first thought is that it rained while you were inside. To confirm this, you look to the sky to identify rain clouds. If the sky is cloudy, you are reasonably sure that it rained. If the sky is clear, you consider another possibility – perhaps sprinklers wet the ground. To confirm this, you look for sprinklers in the immediate area. If they are found, you are reasonably sure of why the ground is wet. If no sprinklers are found, you consider another possibility and the cycle repeats. Each time you consider a possible cause, you search for supporting evidence to confirm that cause. You accept or reject a possibility based on the presence or absence of supporting evidence. In the above scenario, you observe a water truck spraying an adjacent construction site. You are now reasonably sure of how the ground became wet. The wet ground was your observation. The possibility of rain was your first hypothesis. Searching the sky for clouds was your experimentation. The absence of clouds in the sky caused you to reject your hypothesis. Other hypotheses were considered and subsequently rejected based on a lack of supporting evidence. Finally, the water truck hypothesis was confirmed when you saw the truck in the immediate area. Your determination that the water truck wet the ground is your conclusion or theory. This deductive procedure is termed the scientific method: the process used to form theories. It begins with an observation: the discovery and recognition of some type of unexplained phenomenon. The observation is followed by the hypothesis: the proposal of a possible cause of the observation. The hypothesis is tested during the experimentation phase using experiments specifically designed to prove the hypothesis. If experimental results do not support the hypothesis, another possibility is considered and tested. If the experiments are successful and repeatable, the hypothesis becomes a theory and is presented to the scientific community.
1.3
Forensic Investigation
Imagine a distant planet, similar to earth, with diverse climates and distinctly different environments across its surface. Now imagine that four space programs on earth send their astronauts to the new planet that, by chance, land in different regions characterized as a desert landscape, a tropical rainforest, a frozen landscape, and mountainous landscape. The astronauts explore their regions collecting samples, data, and video from their distinctly different environments. They return to their respective countries with a description of the planet supported by evidence collected during exploration. Each space program presents their information to the world, but the views are conflicting. Each country defends their position and accuses the others of presenting false or misleading information. Whom do you believe? Intuitively, you trust your astronauts and reject the other three despite the fact that, in reality, each is truthful and correct. It is not uncommon for different forensic scientists to arrive at different conclusions after examining the same piece of evidence. This is acceptable, if not expected, in the field of forensic investigation. The results of forensic examinations must never be accepted or rejected because you know or trust one scientist more than another. You must keep an unbiased, open mind, knowing that two or more scientists may present different perspectives when evaluating the same piece of evidence.
1.5
Physical Properties
5
An unfortunate aspect of forensic investigation is that the results of your examination will always have a negative impact on one party. If the evidence supports the suspect’s innocence, the victim is unhappy; if it supports the suspect’s guilt, the suspect is unhappy. This is both unfortunate and unavoidable; however, it is the duty of the forensic chemist to present the unbiased story of the evidence.
1.4
Properties of Matter
Matter is anything that has mass and occupies space. It is difficult to imagine something that has mass that does not occupy space, or something that occupies space that does not have mass. Do not spend too much time pondering the previous, I cannot think of anything either (perhaps something on the previously referenced imaginary planet). Despite the apparent redundancy in the definition of matter, it must satisfy the two parameters. There is a difference between the mass of an object and its weight. Weight is a force resulting from the pull of gravity on a given mass. Mass is defined as a specific quantity of matter and is not affected by the pull of gravity. The weight of an object on earth will be different from its weight on the moon because the force of gravity is different. The mass of an object will be constant at these locations despite the differences in gravitational field strength. For this reason, the term “mass” should always be used in any area of science when referring to “weight.” There are three states (or phases) of matter: solid, liquid, and gas. Solids have a defined volume and a fixed shape; liquids have a defined volume and undefined shape – they conform to the shape of their container; and gases have an undefined volume and undefined shape – they take the shape and volume of the container holding the gas. Elements are the fundamental building blocks of all matter. The symbols used to identify all known elements can be found on the periodic table, an arrangement of the elements based on atomic properties. For example, “H” represents the element hydrogen and “O” represents the element oxygen. Compounds are formed through the combination of two or more elements. Chemical formulas are used to represent compounds. They specify the identity and relative number of each atom present using symbols from the periodic table and subscripts attached to each symbol. For example, the chemical formula for water is H2O, a compound containing two atoms of the element hydrogen (note subscript 2 attached to H) and one atom of the element oxygen. Elements and compounds may exist as pure substances or as mixtures. Pure substances contain only one component and have the same composition throughout, for example, pure gold, pure sugar, and pure water. Mixtures contain two or more pure substances and may be homogeneous or heterogeneous. Homogeneous mixtures have the same composition and properties throughout. They are not pure substances because they contain more than one component. For example, pure sugar water is a homogeneous mixture containing sugar and water. It has the same sweetness throughout; however, evaporating one component (the water) will produce the other (sugar crystals). Heterogeneous mixtures have distinctly different properties within the mixture; water and sand would be an example. The sand and water are easily identified, regardless of the degree of mixing. There are fundamental properties associated with all forms of matter. These distinguishing characteristics may be physical or chemical in nature and are frequently used to identify and classify a particular substance.
1.5
Physical Properties
Physical properties such as eye and hair color, skin tone, and general build are features used to distinguish individuals. Generally, physical properties are of genetic origin and are therefore highly reliable and difficult to conceal. In chemistry, a physical property is anything that can be measured or observed without changing the chemical composition of the substance. The melting point and boiling point of water are both physical properties of water. These temperatures can be measured without changing the chemical composition of water. When water freezes or boils it does not change composition, it merely changes states; ice, liquid water, and steam are all still water. Although melting points and boiling points are physical properties of a substance, the process of melting and boiling results in a physical change: a change in the state of matter, but not its chemical composition. Other physical properties often used in the forensic identification of elements and compounds are color, odor, density, solubility, conductivity, and sublimation. The sublimation of iodine crystals (changing from solid phase directly to gas phase) produces a yellow gas that can stain packaging material and certain types of fabric. This is a distinguishing characteristic of elemental iodine that does not change composition; it is, therefore, a physical property (Fig. 1.1).
6
1
Introduction
Fig. 1.1 The production of gas during sublimation is visible inside a sealed package containing iodine. A substance that has a small temperature range between melting and boiling points will sublime and change from a solid directly to a gas. Note the absence of a liquid phase.
1.6
Chemical Properties
Individuals exposed to the same situation will generally respond differently because most are unique in society. A particular response or action is based on a person’s interpretation or perception of the event, which is often influenced by their morals, ethics, beliefs, etc. How individuals “react” in similar situations may be a distinguishing characteristic. Criminals have no regard for the laws of society and their behavior makes them unique among normal law-abiding citizens. Similarly, how elements or compounds react under carefully controlled conditions may be a distinguishing characteristic. A chemical reaction produces products that are different from the starting material. Chemical properties are a measure of the ability of a substance to produce new substances, or, more simply stated, a measure of the reactivity of a substance. Burning paper produces ash, silver tarnishes, iron rusts; these are all chemical reactions that produce chemical changes. The products are chemically and physically different from the starting material in each case. Paper can burn, silver can tarnish, and iron can rust; these are all chemical properties because they relate to the reactivity of the substance. A matchstick produces fire when struck on the phosphorus-coated side (Fig. 1.1a). This is a chemical property
1.7
Questions
7
Fig. 1.2 The formation of a solid in solution is observable evidence that a chemical reaction has taken place. Chemical properties may be used to detect the presence or absence of specific ions in solution. The different solids indicate the presence of different ions.
of elemental phosphorus. A solution of silver nitrate will produce a white precipitate (solid) in the presence of chloride ions and a yellow precipitate in the presence of iodide ions. These reactions illustrate the unique response of two different ions (chloride and iodide) exposed to the same chemical environment (silver nitrate solution) (Fig. 1.2). Physical and chemical properties are frequently used to identify elements and compounds in the field of forensic chemistry. Therefore, these properties may be used to support or reject specific parts of an investigation. For example, burning is a chemical property associated with heat. A variety of materials will burn; however, they may react differently when exposed to heat. A wall from a house fire would show several distinct burn marks: the wood frame, the wiring in the wall, the paint on the wall, and even the nails in the wood. Burn marks are distinguishing characteristics that provide information beyond the chemical property of combustion. They may be used to determine duration of contact, depth of burn, degree of heat intensity, and source of burn. Fire, hot objects, strong acids, and strong bases will all burn skin; however, each would leave a distinctly different burn mark that would allow identification of a single source from all others. Forensic scientists would use this knowledge to answer specific questions that arise during an investigation.
1.7 1. 2. 3. 4. 5. 6. 7. 8.
9. 10. 11. 12.
Questions Define forensic chemistry. Discuss the difference between chemical analysis and forensic chemical analysis. Use the scientific method to develop a theory based on an observation of your choice. Explain to the members of the jury why two highly qualified scientists presented conflicting testimony when examining the same piece of evidence. Describe the three phases of matter to members of the jury. Explain the difference between a pure substance and a pure mixture. Discuss the difference between a homogeneous and heterogeneous mixture. Identify each of the following mixtures as homogeneous or heterogeneous: (a) Italian dressing (b) Saltwater (c) Steel (d) Soil (e) Spoiled milk Define a physical property. Discuss how physical properties are related to physical changes. Explain to members of the jury the difference between a physical property and a chemical property. Identify each of the following as a chemical change or a physical change: (a) Burning paper (b) Melting butter (c) An explosion (d) Sublimation of dry ice
2
Atomic Structure
2.1
Introduction
At first glance, the periodic table may appear quite intimidating – a collection of seemingly unrelated numbers and symbols thrown together with little thought given to organization, continuity, or relevance. It may be comforting to know that the information contained in the periodic table is simply presented in a manner unfamiliar to most. A few basic skills are all that is required to appreciate the periodic table as a highly organized source of invaluable information.
2.2
Periodic Table
In 1869, a Russian chemist named Dmitri I. Mendeleev (1834–1907) discovered that elements exhibit a repeating pattern of properties when organized in order of increasing atomic mass. He called this observation the periodic law. Mendeleyev arranged the elements in different ways to determine if a relationship among the elements could be established. Frustrated and without success, he finally organized the elements into rows, beginning a new row with each repeating cycle, and the “primitive” periodic table was born. The German chemist Lothar Meyer also observed this “periodic” relationship around the same time, but as fate would have it, Mendeleyev is credited with the discovery because he was the first to organize the elements. The current form of the periodic table was later discovered by Henry Moseley who observed that elements organized by increasing atomic numbers created a more uniform arrangement. The periodic table contains detailed information on all the known elements. The elements are represented by symbols that are translated into names. The symbols contain one-, two-, or three-letter designations that are case sensitive; the first letter is always uppercase with subsequent letters, if present, always lowercase. The names of the elements must be memorized along with their symbols. This task is somewhat simplified by the fact that many of the symbols share a common letter with the name. For example, N is the symbol for nitrogen and O is the symbol for oxygen. Unfortunately, this is not always the case, and some elements appear to have symbols that are completely unrelated to their names (Fig. 2.1). For example, Au is the symbol for gold and Fe is a symbol for iron, etc. In these cases, the symbol is derived from the element’s name in Latin, German, or Greek; for example, Au is derived from the Latin word aurum meaning gold (see Appendix 1 for symbols and names of common elements). The elements are organized into vertical columns called groups and horizontal rows called periods. The group numbers appear at the top of each column in Roman numerals and range from I to VIII (one to eight). Elements in the same group (vertical column) have similar chemical and physical properties and a few groups are given characteristic names that you should become familiar with: Group IA elements are called alkali metals, group IIA are called alkaline earth metals, group VIIA the halogens, and group VIIIA the noble (or inert) gases. The A and B designations associated with the group numbers have no definitive meaning; they are simply used (in the US) to differentiate the main group elements (also called representative elements) from the transition metals. This practice can vary with table suppliers, particularly those from European countries. Nonetheless, the taller group columns located on each side of the table (“A” designations above) are called the main group elements and the middle groups (“B” designations above) are called the transition metals. The periods are numbered on the left side of the table from 1 to 7 downward, beginning with hydrogen.
J.I. Khan et al., Basic Principles of Forensic Chemistry, DOI 10.1007/978-1-59745-437-7_2, © Springer Science+Business Media, LLC 2012
9
10
2
Atomic Structure
1 IA
18 VIIIA
1
1 H 1.01
2 IIA
2
3 Li 6.94
4 Be 9.01
3
11 12 Na Mg 22.99 24.31
4
19 20 21 22 23 24 25 K Ca Sc Ti V Cr Mn 39.10 40.08 44.96 47.88 50.94 52.00 54.94
5
37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe 85.47 87.62 88.91 91.22 92.91 95.94 98.91 101.1 102.9 106.4 107.87 112.4 114.8 118.7 121.8 127.6 126.90 131.3
6
55 56 71 72 73 74 75 76 77 78 79 80 81 82 83 84 Cs Ba Lu* Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po 132.9 137.33 175.0 178.5 180.9 183.9 186.2 190.2 192.2 195.1 196.97 200.59 204.4 207.2 209.0 (209)
7
87 88 103 Fr Ra Lr** (223) (226.0) (262)
13 IIIA
14 IVA
15 VA
16 VIA
17 VIIA
2 He 4.00
5 6 7 8 9 10 B C N O F Ne 10.81 12.01 14.01 16.00 19.00 20.18 3 IIIB
4 IVB
104 Rf (261)
5 VB
105 Db (262)
6 VIB
106 Sq (263)
7 VIIB
107 Bh (262)
8 VIIIB
9 VIIIB
10 VIIIB
11 IB
12 IIB
13 14 15 16 17 18 Al Si P S Cl Ar 26.98 28.09 30.97 32.06 35.45 39.95
26 27 28 29 30 31 32 33 34 35 36 Fe Co Ni Cu Zn Ga Ge As Se Br Kr 55.85 58.93 58.71 63.55 65.38 69.72 72.59 74.92 78.96 79.90 83.80
85 At (210)
86 Rn (222)
108 109 Hs Mt (265) (266)
57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 La Ce Pr Nd Pm Sm Eu Gd Tb Dy Ho Er Tm Yb Lu 138.9 140.1 140.9 144.2 (147) 150.4 152.0 157.3 158.9 162.5 164.9 167.3 168.9 173.0 175.0 *Lanthanides **Actinides
89 90 91 92 93 94 Ac Th Pa U Np Pu 227.0 232.0 (231) 238.0 (237) (244)
95 Am (243)
96 97 Cm Bk (247) (247)
98 Cf (251)
99 Es (252)
100 101 Fm Md (257) (258)
102 No (259)
103 Lr (260)
Fig. 2.1 Periodic table of the elements (reprinted with permission from Dr. Thomas Basiri, Professor of Chemistry, Victor Valley College. Copyright 2008).
The periods extend left to right across the entire table. All periodic tables have a distinct line of separation running step-wise from boron/aluminum (B/Al) to polonium/astatine (Po/At). This line separates the metals to the left and the nonmetals to the right. The shaded elements bordering the line are called metalloids or semi-metallics because they possess both metallic (metal) and nonmetallic (nonmetal) properties. Metallic character decreases as you move left to right across a given period. Group IA and IIA elements are the most metallic and group VIIA and VIIIA are the most nonmetallic. A transition from metallic to nonmetallic character occurs through the group B elements and is the reason they are termed transition metals. The number above each symbol is called the atomic number and the number below each symbol is called the mass number. These numbers and their significance will be discussed below.
2.3
Atomic Structure
Elements are the fundamental building blocks of matter. Atoms are the smallest, indivisible unit of an element that retains all chemical and physical properties of the element. For example, a single atom of gold has the same physical and chemical properties as 10 tons of gold. Atoms are composed of three subatomic particles: protons, neutrons, and electrons. The protons and neutrons are located at the center of the atom in a region termed the nucleus. The mass number represents the mass of the nucleus or the total mass of protons and neutrons. The electrons are located in three-dimensional regions around the nucleus called orbitals. A large portion of any atom is empty space. The nucleus is surrounded by electrons in regions (orbitals) that are separated by great distances on a relative scale. Electrons located furthest from the nucleus, the outermost electrons, are called valence electrons and determine the chemical and physical properties of each element (Fig. 2.2).
2.4
Subatomic Particles
11
Fig. 2.2 The nucleus of subatomic particles is surrounded by electrons in orbital regions.
2.4
Subatomic Particles
Protons (p +) are positively charged subatomic particles located in the nucleus. The total number of protons in the nucleus is given on the periodic table by the atomic number and positively identifies the element. A change in the number of protons changes the identity of the element; therefore, different elements must have different atomic numbers. A proton has a mass of one atomic mass unit (1 a.m.u = 1.66 × 10 −24 g) and is comparable in size to a neutron. Neutrons (n) are neutral subatomic particles also located in the nucleus. They carry no charge and therefore do not affect nuclear charge or the number of electrons in a neutral atom. Neutrons do contribute significantly to the mass of the atom (nuclear mass) because their mass is about the same as a proton. A change in the number of neutrons will change the mass number, but not the identity of the element. Atoms that contain the same number of protons but have different mass numbers are called isotopes. The number of neutrons contained in any nucleus is determined by subtracting the atomic number from the mass number. Mass number = # of neutrons + # protons (atomic number) Rearrange: # of neutrons = mass number – # protons (atomic number) Electrons (e−) are negatively charged subatomic particles located around the nucleus in predictable regions called orbitals. In a neutral atom, the number of electrons (negatives) is equal to the number of protons (positives). A change in the number of electrons in a neutral atom creates an ion, an electrically charged atom. Ions may carry a positive or negative charge depending on the number of electrons relative to the number of protons. The mass of an electron is approximately 2,000 times smaller than that of a proton or a neutron. As a result, electrons do not contribute significantly to the overall mass of the atom. An atom is composed of two distinct regions – the nucleus and the region immediately surrounding the nucleus. The nucleus contains only protons and neutrons and is therefore positively charged. The region immediately surrounding the nucleus contains only electrons and is negatively charged. Protons and electrons are the only subatomic particles that are electrically charged. The charges are of equal magnitude despite the extreme disparity in mass, that is, an electron’s charge will cancel a proton’s charge. The overall charge on an atom is determined by comparing the number of protons to the number of electrons. If the number of electrons is greater than the number of protons (atomic number), the atom carries a negative charge; if the number of electrons is less, the atom carries a positive charge; if they are equal, the atom is neutral. The net charge on an atom in its standard state (natural conditions) is always zero (Fig. 2.3).
12
2
Atomic Structure
Fig. 2.3 Note how the net charge of protons and electrons determines if an atom’s charge is neutral (0), positive (+), or negative (−).
2.5
The Arrangement of Electrons in an Atom
I grew up in a small town in upstate New York. On hot summer nights, our yard would fill with lightning bugs – interesting little flying creatures that periodically emit high-intensity light. When we were young, my sister and I would catch these elusive flying insects and put them in jars. We would punch out some small air holes in the lids, maybe throw in a piece of lettuce, and proudly display our new pets. Unfortunately, few ever saw the next night, a crushing reality to two small children. Imagine that you catch a single lightning bug and starve him for a few hours (incidentally, you did catch a male). You release your famished pet near a tree where you have graciously prepared a gourmet lightning bug dinner (you do, of course, know the diet of nocturnal insects!). You direct a camera at the food and take a time-lapsed photo over the remainder of the night (Fig. 2.4). You would be very confident that, at any given time, there would be a high probability of finding the lightning bug in the region near the food. This statement is based on knowledge you possess, specifically, you know he is hungry. Your photo would most likely support your statement. You would see a region, or distribution, of light from the insect around the food. It is possible to find the lightning bug far from the food, but not likely given his current state of hunger. Electrons behave in a similar manner around the nucleus. It is not possible to know exactly where the electrons are; however, we can define regions where there is a high probability of finding them. Electrons are not randomly distributed around the nucleus; they are confined to specific energy levels called orbitals. At the subatomic level, it is not practical to use common units of length to measure distances, that is, it is not commonly stated that a specific electron may be 2 nm from the nucleus. Instead, we use energy to define distances. The electrons fill outward from the nucleus with the lowest energy, most stable electrons occupying regions close to the nucleus. The arrangement is very similar to an onion except great distances separate the
2.6
Electron Configurations
13
Fig. 2.4 The author’s childhood experiment with lightning bugs shows a similarity with the relationship between electrons and the nucleus of an atom.
individual “peels.” Thus, in comparing two electrons of different energy, it would be stated that electrons of higher energy are located further from the nucleus. The energy of an electron is well defined and only certain energies are allowed (we call this quantized). If you have trouble with this statement, consider the musical tones created when you blow across the top of a bottle containing a fixed volume of water. It is not possible to create a full musical scale under these conditions. You hear only octaves or specific, allowable musical tones. The same can be said of an electron; it can have only specific, allowable energy values. This energy determines the location of the electron around the nucleus (remember, energy equates to distance; therefore, specific energy values translate to specific distances). The first levels of electron arrangement are “energy shells” called principal energy levels. They are given by the period numbers from the periodic table; for example, H and He represent period 1 and have electrons in principal energy level 1, Li, Be, B, C, N, O, F, and Ne represent period 2 and have electrons in principal energy level 2, and so forth. These regions (shells) increase in both size and energy as their distance from the nucleus increases. Principal energy level 1 is the lowest energy level (and smallest); therefore, electrons occupying this region are closest to the nucleus. Electrons occupying successively higher levels possess greater energy and are further from the nucleus. The principal energy levels are further divided into sublevels, or orbitals, designated s, p, d, and f. The orbitals are regions around the nucleus where there is a high probability of finding an electron of specific energy. Electrons occupy orbitals within principal energy levels and the energy of the electron determines which orbital it resides in and therefore its location around the nucleus. It may be helpful to compare electron arrangement to people staying at a hotel (I know…but bear with me!). First, hotels vary in size; some can have several floors with many rooms, while others have only a few floors with a small number of rooms (different atoms). Different people (the electrons) stay in different rooms (the orbitals) on different floors (the principal energy levels). Also, people are obligated to stay in only one room and generally cannot roam around and stay in any room they choose (specific energy of the electron).
2.6
Electron Configurations
Electron configurations illustrate the arrangement of electrons around the nucleus of an atom. The aufbau principle is used to construct electron configurations for ground-state (neutral) atoms and ions (aufbau: German for “build-up”). To determine the order that electrons fill around the nucleus, we must first construct the aufbau triangle (Fig. 2.5).
14
2
Fig. 2.5 An example of an aufbau triangle.
Atomic Structure
1s 2s 2p 3s 3p
3d
4s 4p
4d
4f
5s 5p
5d
5f
6s
6p 6d
6f
7s
7p 7d
7f
Draw the triangle as shown in Fig. 2.5; notice all rows contain the same number and all columns contain the same orbital (row three contains all 3’s and the first column contains all s-orbitals). Draw parallel lines through the orbital designations as shown. Follow the arrows tail to head, beginning with 1s, and write the sequence: 1s2s2p3s3p4s3d…, etc. This is the sequence used to fill electrons around a nucleus. The electrons are located in orbitals (s, p, d, f) within principal energy levels (1, 2, 3, 4, etc.). To write an electron configuration, the number of electrons contained in the atom or ion must be calculated. Recall that protons and electrons are the only subatomic particles that carry a charge. In a neutral atom, the net charge is zero. This neutral state exists only when the number of electrons (negative charges) equals the number of protons (positive charges). Therefore, the number of electrons around the nucleus of a neutral atom is given by the atomic number. The following example illustrates how to write electron configurations. We will limit our discussion to main group elements only, that is, no transition metals. Example: Write the electron configuration for Na. First, determine the number of electrons in a neutral sodium atom. The periodic table gives an atomic number of 11 for Na. This means that there are 11 protons, or positive charges, in the nucleus of a sodium atom. Because no charge is written on the atom in our example, the number of electrons (negative charges) must also be 11. Next, write a segment of the aufbau sequence. 1s2s2p3s3p4s3d The number of electrons in each orbital is shown as a superscript attached to the orbital designation. The maximum number of electrons in an orbital: s-orbital is 2, p-orbital is 6, d-orbital is 10, and f-orbital is 14. The orbitals fill from lowest to highest energy and you cannot add electrons to higher levels until the preceding level is full. Revisiting our hotel analogy, you must fill the first floor before adding to the second; fill the second before adding to the third, etc. We start with the 1s orbital, principal energy level 1 containing a single s-orbital. We fill the orbital by placing a superscript 2 on the 1s designation (s-orbitals have a maximum occupancy of two electrons). Principal energy level 2 is filled next and contains a 2s and 2p orbital. The 2s orbital is filled in a manner similar to the 1s. The 2p orbital is filled using a superscript 6 attached (p-orbitals have a maximum occupancy of six electrons). We add the superscripts and find we have accounted for ten electrons. We have 11 electrons in total; so, the next orbital in our sequence (the 3s) will contain a single electron shown as a superscript of 1. The complete electron configuration for neutral Na is shown below. 1s2 2s2 2p6 3s1 3p4s3d Our segment is too long so we simply erase the unused orbitals. If our segment was too short, we would add more orbitals to our sequence from the aufbau triangle. The electron configuration for Na would be written as: Na - 1s2 2s2 2p6 3s1 We would “read” this, 1s two, 2s two, 2p six, 3s one. The superscript on the last orbital depends on the number of electrons required to complete the configuration. It can be any number up to the maximum allowed in the orbital but can never exceed the maximum. Valence electrons are electrons in the outermost principal energy level. This may or may not be the last orbital written.
(
)
Na 11e - - 1s2 2s2 2p6 3s1
2.6
Electron Configurations
15
The outermost principal energy level containing electrons is level 3. Counting all electrons in level 3, we have 1 valence electron. In this case, the outermost level was the last one written.
( )
O 8e - - 1s2 2s2 2p 4 If we examine the electron configuration for oxygen, we see that the outermost principal energy level is 2. We have two orbitals in level 2 containing a total of 6 valence electrons, 2 in the 2s and 4 in the 2p (add the superscripts). In this case, the outermost level included the last two orbitals written. Care must be taken when determining the number of valence electrons; do not immediately jump to the last orbital and use its superscript. By chance, sometimes it is the last orbital, but sometimes it is not. Valence electrons occupy the highest principal energy level (level…level), not orbital (I think that I’ll stop beating that horse now!). The valence electrons determine the chemical and physical properties of the element. If two atoms were brought together during the course of a chemical reaction, their first point of contact would be the electrons in the outermost levels. If we know the electron configuration, and, therefore, the valence configuration, we can make predictions on properties and reactivity. Core electrons are located in levels below the valence electrons and generally do not influence reactivity. The electron configurations for group I elements Li, Na, and K are shown below.
( ) Na (11e )- 1s 2s 2p 3s K (19e )- 1s 2s 2p 3s 3p 4s Li 3e - - 1s2 2s1 2
-
2
-
2
2
6
6
1
2
6
1
If we look closely at the configurations, we see that each ends with s1, a single electron in the outermost energy level. It is no coincidence that all the above elements are members of group I. The group numbers on the periodic table represent the number of valence electrons for each member of the group. Group I elements have 1 valence electron, group II elements have 2, group III elements have 3, etc. Some members of group II:
( ) Mg (12e )- 1s 2s 2p 3s Ca (20e )- 1s 2s 2p 3s 3p 4s Be 4e - - 1s2 2s2 -
2
-
2
2
2
6
6
2
2
6
2
Some members of group VII:
( ) Cl (17e )- 1s 2s 2p 3s 3p F 9e - - 1s2 2s2 2p5 -
2
2
6
2
5
Electron configurations for ions are constructed in a similar manner except the charge must be considered in determining the total number of electrons. For ions, the number of electrons is calculated by subtracting the charge on the ion (with its sign) from the atomic number. # e - (for ions ) = atomic number (# of protons ) - (charge ) Using the above relationship, we can calculate the total number of electrons contained in each of the following ions: N 3- N has atomic number 7; # e - = 7 - ( - 3) or 10eS2 - S has atomic number 16; # e - = 16 - ( - 2) or 18eBr - Br has atomic number 35; # e - = 35 - ( - 1) or 36e Na + Na has atomic number 11; # e - = 11 - ( + 1) or 10e Ca 2 + Ca has atomic number 20; # e - = 20 - ( + 2) or 18e Notice that negative ions have more electrons than protons and positive ions have fewer electrons than protons. Ions are created by changing the number of electrons relative to the number of protons. It is worth noting that moving around electrons is not rocket science, if you have ever rubbed a balloon on your head and stuck it on a wall you have accomplished this miraculous feat. Below are the electron configurations for N3−, O2−, F−, Ne, Na+, and Mg2+.
16
2
( ) O (10e )- 1s 2s 2p F (10e )- 1s 2s 2p Ne (10e )- 1s 2s 2p Na (10e )- 1s 2s 2p Mg (10e )- 1s 2s 2p
Atomic Structure
N3 - 10e - - 1s2 2s2 2p6 2-
+
2+
2
-
2
6
-
2
2
6
-
2
2
6
-
2
2
6
-
2
2
6
The above configurations are identical and each contains a total of 10 electrons with eight valence electrons (remember our dead horse; valence electrons occupy the highest principal energy level, which is 2 in this case). Although the configurations are identical, the charges on the ions vary and only one atom in our group is neutral. Neon is a “noble gas” or “inert gas,” names given to all group VIIIA elements. Chemical reactivity is a stability-driven process – if products are more stable than reactants (starting material), the reaction occurs. The noble gases are extremely stable and show very little reactivity because of filled outer shell configurations. In the above examples, principal energy level 2 (the outer level or shell) is full; principal energy level 2 has only s and p orbitals. The addition of a single extra electron to any of the above configurations would require occupancy in the next higher energy shell, specifically the 3s orbital. A filled outer shell configuration is achieved when all orbitals in the outermost level are full. Generally, this is achieved with eight valence electrons. The tendency of atoms to gain or lose electrons to obtain electron configurations similar to group VIII elements is called the octet rule. The configurations above, all satisfy the octet rule and represent the elements in their most stable forms. The charges on the atoms result from a gain or loss of electrons in order to achieve a configuration identical to Ne. There are exceptions to the octet rule. For example, helium (He) is a group VIIIA element that has an electron configuration of 1s2. Principal energy level one contains only the 1s-orbital and requires only two electrons to fill. Helium satisfies this condition and has therefore achieved its octet. There is a difference between the ground state of an element and its most stable state. The ground state is how the atom is most often found in nature and occurs when the atom is neutral. The most stable state is when the atom has achieved an octet, or filled outer shell configuration. This will generally require the atom to carry an overall net charge as a result of gaining or losing electrons. The group numbers provide us with important information on both states. We know that the number of valence electrons for a particular atom is given by the group number. However, what may have escaped our attention is that the group number gives the valence electrons for neutral atoms only; group I elements have 1 valence electron, group II have two, etc. Let us revisit our configurations above for N3−, O2−, F−, Ne, Na+, and Mg2+; all contain eight valence electrons regardless of their group number, but none are neutral except Ne (you guessed it, a group VIIIA element). Consider the following examples, paying close attention to the differences in electron configuration and how this relates to charge in the most stable state: Natural state of sodium – Na (11e−) – 1s22s22p63s1 Most stable state of sodium – Na+ (10e−) – 1s22s22p6 Natural state of magnesium – Mg (12e−) – 1s22s22p63s2 Most stable state of magnesium – Mg2+ (10e−) – 1s22s22p6 Natural state of aluminum – Al (13e−) – 1s22s22p63s23p1 Most stable state of aluminum – Al3+ (10e−) – 1s22s22p6 Natural state of nitrogen – N (7e−) – 1s22s22p3 Most stable state of nitrogen – N3− (10e−) – 1s22s22p6 Natural state of atomic oxygen – O (8e−) – 1s22s22p4 Most stable state of atomic oxygen – O2− (10e−) – 1s22s22p6 Natural state of atomic fluorine – F (9e−) – 1s22s22p5 Most stable state of atomic fluorine – F− (10e−) – 1s22s22p6 Relating the group number to the octet rule can provide information on the most stable state of group members. Group I elements have one valence electron and can obtain an octet (eight electrons in the outermost principal energy level) in two ways: lose one electron and take a +1 charge or gain seven electrons and take −7 charge. The more favorable choice would be to lose one electron and become +1. Groups IA, IIA, and IIIA lose electrons to achieve their octets and take charges of +1, +2, and +3, respectively, in their most stable forms. Group IV is unusual and will not be discussed at this point. Groups VA, VIA, and VIIA will gain electrons to complete their octets, taking charges of −3, −2, and −1, respectively, in their most stable forms. We can summarize these observations by stating: to satisfy the octet rule and achieve stable electron configurations, metals must lose electrons and nonmetals must gain electrons.
2.7
Periodic Trends: Understanding the Periodic Table
17
Table 2.1 Orbitals within each principal energy level and the maximum number of electrons contained in each Orbital s p d f Principal Number of energy level orbitals 1 1 Maximum number of electrons in principal energy level 1 is 2 2 2 Maximum number of electrons in principal energy level 2 is 8 3 3
Maximum number of electrons in principal energy level 3 is 18 4 4
Maximum number of electrons 2 6 10 14 Orbital designation 1s
Maximum number of electrons 2
2s 2p
2 6
3s 3p 3d
2 6 10
4s 4p 4d 4f
2 6 10 14
Table 2.2 Electron distribution in atomic orbitals Principal energy level (n) 1 2 3 4
Formula 2n2 2 × (12) 2 × (22) 2 × (32) 2 × (42)
Maximum number of electrons 2 8 18 32
Table 2.1 shows the orbitals within each principal energy level and the maximum number of electrons contained in each. Notice that not all principal energy levels contain all orbitals. The maximum number of electrons contained in a principal energy level can be calculated using the formula 2n2, where n is the principal energy level (period number from the periodic table) (Table 2.2).
2.7
Periodic Trends: Understanding the Periodic Table
The periodic table is an arrangement of the elements based on similarities in atomic properties. It can therefore be used to predict the chemical and physical properties of elements. Electronegativity is a measure of an atom’s desire for electrons or the ability of an atom to draw electrons toward it. Fluorine (F) is the most electronegative element on the periodic table and, in general, the periodic trend is that the closer an element is to fluorine, the greater is its electronegativity. If asked which element, Br or Ca, has the greater ability to draw electrons, you would respond Br because it is closer to fluorine. The nonmetals are grouped near fluorine on the periodic table and must gain electrons to achieve octets; as a result, they have high electronegativities. Metallic elements, particularly groups IA and IIA, are not near fluorine on the periodic table. They must lose electrons to achieve octets and therefore have low electronegativities. The importance of electronegativity in chemical bonding cannot be overstated and a good rule of thumb is “the closer an element is to fluorine on the periodic table, the greater is its electronegativity” Theoretically, the atomic radius of an atom is the distance from the center of the nucleus to the outer boundary of the atom. However, regions containing the valence electrons (outermost) do not have distinct boundaries. Not to worry; when two atoms of the same element are bound together, the centers of their nuclei are separated by a measurable distance. Therefore, the atomic radius of an atom is defined as half the distance between the centers of two bonded atoms of the same element; for example, the atomic radius of a single hydrogen atom is equal to half the distance from the centers of two bonded hydrogen atoms. Atomic radii increase down a given group of elements and, in general, decrease left to right across a period (Fig. 2.6).
18
2
Atomic Structure
Atomic radius decreases 18 VIIIA 2 He 4.00
2 IIA
13 14 15 16 17 IIIA IVA VA VIA VIIA 5 6 7 8 9 10 B C N O F Ne 10.81 12.01 14.01 16.00 19.00 20.18
2
3 Li 6.94
4 Be 9.01
3
11 12 Na Mg 22.99 24.31
4
19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 K Ca Sc Ti V Cr Mn Fe Co Ni Cu Zn Ga Ge As Se Br Kr 39.10 40.08 44.96 47.88 50.94 52.00 54.94 55.85 58.93 58.71 63.55 65.38 69.72 72.59 74.92 78.96 79.90 83.80
3 IIIB
4 IVB
5 VB
6 VIB
7 VIIB
8 9 10 VIIIB VIIIB VIIIB
11 IB
12 IIB
13 14 15 16 17 18 Al Si P S Cl Ar 26.98 28.09 30.97 32.06 35.45 39.95
37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe 85.47 87.62 88.91 91.22 92.91 95.94 98.91 101.1 102.9 106.4 107.87 112.4 114.8 118.7 121.8 127.6 126.90 131.3 55 56 57 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 6 Cs Ba La* Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po At Rn 132.9 137.33 138.9 178.5 180.9 183.9 186.2 190.2 192.2 195.1 196.97 200.59 204.4 207.2 209.0 (209) (210) (222)
5
7
Electronegativity increases
Atomic radius decreases
1 IA 1 1 H 1.01
87 88 89 104 105 106 107 108 109 Fr Ra Ac** Rf Db Sq Bh Hs Mt (223) (226.0) (227) (261) (262) (263) (262) (265) (266) Electronegativity increases
Fig. 2.6 Understanding periodic trends.
2.8
Isotopes
Atoms that contain the same number of protons but have different mass numbers are called isotopes. Isotopes of an element differ only in the number of neutrons contained in the nucleus. Typically, atomic nuclei are most stable when they contain a certain number of protons and neutrons. The addition of neutrons to the nucleus increases the mass of the atom and creates instability. For example, the most abundant form of hydrogen contains a single proton in the nucleus. The addition of a neutron to a hydrogen nucleus creates an isotope of hydrogen called deuterium. Deuterium is a heavier and more energetic form of hydrogen, and is therefore less stable. The addition of a second neutron creates a third isotope of hydrogen called tritium, the most unstable and active form of hydrogen. The instability of isotopes is a direct result of increased nuclear mass and is detected through a release of energy called nuclear radiation (Fig. 2.7).
2.9
Radioactivity
Dig a ditch in 100° or take a nap on the couch; well, there is a tough choice. The relationship between energy and stability is a common thread that unifies most areas of science (and based on your response to my question, it appears that it extends into our daily lives as well). High energy translates to instability and there is always a natural tendency toward lowest energy and greatest stability (the nap on the couch). This is inescapable; however, I would not try this argument the next time your asked to do yard work, it does not work, believe me. The response of an atom to high energy is not much different from our own. It will not remain unstable indefinitely; eventually, the nucleus will emit energy in an effort to regain stability (its version of a nap). The spontaneous emission of high-energy nuclear radiation from an unstable nucleus is termed radioactivity (or radioactive decay). Atoms that exhibit this property are said to be radioactive and most elements with an atomic number of 90 or greater have radioactive isotopes. Early experiments identified three types of nuclear radiation: alpha (a), beta (b), and gamma (g) rays. A sample of radioactive material is placed between the positive and negative poles of a magnet and emitted radiation is detected using a piece of X-ray film placed at the top of the apparatus (Fig. 2.8).
2.11
Nuclear Radiation: Forensic Applications
19
Fig. 2.7 As the nuclear mass of an element increases, so does the isotopes instability.
Fig. 2.8 A magnet is used to measure the emission of radioactivity from sample material.
Three spots were observed at different locations on the film. Two spots were deflected toward opposite poles of the magnet, whereas the third passed straight through, apparently unaffected. This implies that two of the particles are electrically charged and the third is neutral. Alpha (a) rays are positively charged particles that are deflected toward the negative pole and beta (b) rays are negatively charged particles deflected toward the positive pole. Gamma (g) rays have no detectable charge (or mass) and therefore passed straight through.
2.10
Types of Radioactive Decay
The release of a helium nucleus (He2+) during radioactive decay is called a-decay (alpha decay). This type of decay is a lowenergy emission of positively charged particles. A thin sheet of paper will provide adequate protection against this type of radiation. The release of electrons (e−) during radioactive decay is called b-decay (beta decay). This type of decay produces negatively charged particles of medium energy. A few hundred sheets of paper are required to provide adequate protection against this type of radiation. The release of electromagnetic radiation during radioactive decay is called g-decay (gamma decay). This type of decay produces high-energy, neutral radiation capable of penetrating a 1-inch-thick wall of lead. This is the most dangerous and destructive form of radioactive decay.
2.11
Nuclear Radiation: Forensic Applications
Radioactive isotopes will lose intensity (gain stability) over time because of a-, b-, or g-decay. The amount of time required for radioactive intensity to decrease by half is called the half-life. Carbon-14 is a radioactive isotope of carbon with a half-life of 5,720 years. A 100-g sample of radioactive carbon-14 will contain 50 g of active carbon-14 in 5,720 years, 25 g after an additional 5,720 years, and so on. Half-lives can range from fractions of a second to millions of years, depending on the isotope.
20
2
Atomic Structure
Table 2.3 The atomic number, atomic mass, and molar mass of selected elements Element H (hydrogen) He (helium) Li (lithium) C (carbon) N (nitrogen) O (oxygen) F (fluorine) Na (sodium) P (phosphorous) Cl (chlorine) I (iodine)
Atomic number 1 2 3 6 7 8 9 11 15 17 53
Mass of 1 Atom (atomic mass) 1.01 a.m.u. 4.00 a.m.u. 6.94 a.m.u 12.01 a.m.u. 14.01 a.m.u. 16.00 a.m.u. 19.00 a.m.u. 22.99 a.m.u. 30.97 a.m.u. 35.45 a.m.u. 126.90 a.m.u.
Mass of one mole (molar mass) 1.01 g 4.00 g 6.94 g 12.01 g 14.01 g 16.00 g 19.00 g 22.99 g 30.97 g 35.45 g 126.90 g
Forensic anthropologists use this information to determine the age of ancient artifacts, mummies, bones, and other material. Radioactive dating is a common technique accepted worldwide.
2.12
The Mole and Molar Mass
The atomic mass of carbon from the periodic table is 12.01, but 12.01 of “what”? Curiously, no “mass” units are given on the periodic table with “mass numbers.” The reason is that mass numbers can have two equally important units: atomic mass units (a.m.u.) or grams. The preferential inclusion on the table of one unit over the other would undoubtedly spark a never-ending debate, dividing educators and authors worldwide. To avoid this debacle, and the certain demise of the modern world, no units are given; after all, the last thing we need is another source of debate. I momentarily digress, let us return to carbon: 12.01 amu’s of carbon represents the mass of one carbon atom, 12.01 g of carbon represents the mass of 6.02 × 1023 atoms of carbon. The mass number in amu’s of any element represents the mass of one atom of the element, whereas the mass number in grams represents the mass of 6.02 × 1023 atoms of the element. The mass “numbers” are the same; it is the units that distinguish the difference. If you were asked how many pencils are in a dozen pencils, you would reply 12. We associate the word “dozen” with the number “12” and define a dozen as anything that contains 12 “things.” The same is true of a mole, an extremely important quantity used in chemistry. A mole is defined as anything that contains 6.02 × 1023 particles or “things.” We associate the number 6.02 × 1023 with the word “mole.” We can simplify our example above by stating: the atomic mass of any element, in grams, contains 6.02 × 1023 atoms of the element, or one mole of the element, and is called the molar mass. The quantity that defines a mole, 6.02 × 1023, is called Avogadro’s number in honor of its founder, the nineteenth-century Italian scientist Amadeo Avogadro.
2.13
Elements of Forensic Interest
See Table 2.3 for the elements of forensic interest.
2.14
Questions
1. Write the names of the elements represented by the following symbols: (a) I (b) P (c) Na
Suggested Reading
21
2. Write the symbols for the following elements: (a) Potassium (b) Nickel (c) Manganese (d) Magnesium 3. Name the three types of subatomic particles and give their location in the atom. 4. Provide the mass that contains: (a) One atom of carbon (b) One mole of magnesium (c) 6.02 × 1023 atoms of Li (d) 3.01 × 1023 atoms of Ca 5. Please explain to the members of the jury how two atoms of the same element can have different mass numbers. 6. Define radioactivity and the three types of nuclear radiation. 7. Cite a few examples of the application of radioactive decay to forensic investigation. 8. Explain the aufbau principle. 9. Give the maximum number of electrons in: (a) Principal energy level 2 (b) A p-orbital (c) Principal energy level 4 (d) The 4f-orbital (e) The 1s-orbital 10. Briefly explain to the members of the jury the difference between a neutral atom and an ion. How are ions formed? 11. Write the electron configuration for each of the following: (a) Na (b) F− (c) Mg2+ (d) Li+ (e) Ar 12. Explain why the electron configurations for N3−, O2−, F−, Ne, Na+, and Mg2+ are identical. 13. What information does the group numbers of the periodic table give? 14. Describe the difference between the natural state of an atom and its most stable state. 15. Describe the periodic trends of electronegativity and atomic radius.
Suggested Reading Jones, L.; Atkins, P. Chemistry: Molecules, Matter, and Change, 4th ed.; W.H. Freeman and Company: New York, 2002; pp 298–299, pp 959–964.
3
Molecules
3.1
Introduction
Compounds are formed through the combination of two or more elements held together by chemical bonds. The number and identity of each atom present in the compound are given by the chemical formula. Symbols from the periodic table are used to identify atoms, and the relative number of each atom present is indicated using a subscript attached to the symbol. Subscripts are used only when two or more atoms of the same element appear in the formula. The symbol without a subscript is used to represent the presence of a single atom in the formula. For example, H2O is the chemical formula for water, a compound containing one atom of oxygen bound to two atoms of hydrogen. Compounds are electrically neutral and divided into two broad classes based on the type of chemical bond present: ionic bonds form ionic compounds and covalent bonds form covalent compounds. It is important to note that pure ionic and pure covalent represent the extremes of chemical bonding and rarely exist. The vast majority of chemical bonds contain both ionic and covalent character and classification is based on the type present in the highest percentage. For example, a bond that contains a higher percentage of ionic character is termed ionic; however, this does not mean that the bond contains no covalent character. Characterizing chemical bonds as ionic or covalent is a common, reliable practice that is universally accepted. This convenient language will be used to study bonding and structural properties in this chapter.
3.2
Chemical Bonding
Valency is the number of bonds that a particular atom must form to achieve a neutral state. It is directly related to the octet rule and measures an atom’s ability to gain, lose, or share electron(s) when forming chemical bonds. We have already established a relationship between group number, valence electrons, and an atom’s ability to gain or lose electrons (the octet rule). We may therefore confidently predict that a relationship between group number and valency exists; we are correct indeed. Although the valency of many elements is considered fixed, there are exceptions. These cases rarely have applications in forensic chemistry and, therefore, will not be discussed.
3.2.1
Ionic Bonds
Ionic bonds are electrostatic forces of attraction between two ions resulting from a transfer of electrons. This is an elaborate way of saying “opposites attract.” This type of chemical bond is very similar to the attractive forces that hold the opposite poles of two magnets together. Ionic bonds are usually formed between metals and nonmetals, that is, between elements with low electronegativities and elements with high electronegativities. The metal will transfer electrons to the nonmetal resulting in a net charge on both as the ions achieve octets. For example, the chemical formula for common table salt is NaCl. The periodic table shows Na (a metal) in group IA and Cl (a nonmetal) in group VIIA; recall the division line on the periodic table separating metals to the left and nonmetals to the right. The Na atom transfers its single valence electron to Cl and takes a charge of positive one (+1); the Cl atom accepts the electron and takes a charge of negative one (−1). The two ions are attracted (because opposites attract) and an ionic bond is formed. In the mutually beneficial transfer, the octets of both atoms are satisfied.
J.I. Khan et al., Basic Principles of Forensic Chemistry, DOI 10.1007/978-1-59745-437-7_3, © Springer Science+Business Media, LLC 2012
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In reality, Na has no choice. A “conversation” between the two atoms might contain the following dialog: the highly electronegative Cl atom says, “I’m stronger than you, I want your electron and there’s not much you can do about it.” Na atom responds, “go ahead and take that electron, it’s so far from the nucleus I have trouble keeping track of it anyway.” The Cl atom steals or snatches the electron and both ions achieve an octet as a result. The electron transfer is illustrated in Fig. 3.1 (dots represent valence electrons). Ionic compounds exist as crystal lattice structures containing ions packed together and held by ionic bonds. The ratio of ions in the crystal is given by the chemical formula. For example, common table salt (NaCl) exists as a crystal containing a large number of Na+ and Cl− ions. The total number of ions may vary from crystal to crystal; however, the ratio of Na+ to Cl− is given by the chemical formula and is one to one. In this model, the existence of a single molecule of NaCl is somewhat obscure. Therefore, it is generally improper and incorrect to refer to any compound containing a metal as a molecule. Accordingly, chemical formulas for ionic compounds represent formula units, not molecules. There are a few exceptions; but they are rare indeed. We shall see that the term “molecule” is reserved for compounds containing only nonmetals. Ionic bonds are attractive forces between oppositely charged ions. The charges result from a transfer of electrons from elements of low electronegativity to elements of high electronegativity. A transfer of electrons is not the only method used by atoms to achieve an octet.
3.2.2
Covalent Bonds
Covalent bonds are formed when two nuclei share electrons. This type of chemical bond is typically found in compounds containing only nonmetals. Consider the formation of a hydrogen molecule, H2 (Fig. 3.2). Hydrogen is not a metal despite
Fig. 3.1 Electron transfer in the formation of an ionic bond and the resulting formula unit. The ions are attracted by magnetic forces and arranged symmetrically into a crystal.
Fig. 3.2 Valence electrons from separate atoms are attracted into the internuclear space forming a molecule. The equally shared electrons form a covalent bond linking the two nuclei.
3.2
Chemical Bonding
25
Fig. 3.3 The polarity of water results from the magnetic properties of the two polar covalent bonds between hydrogen and oxygen. The nonbonding electrons on oxygen (dots) repel the bonding electrons between hydrogen and oxygen (lines) producing the observed bent geometry.
its location on the periodic table. It is a member of group I simply because it has an electron configuration similar to group I elements (1s1). As the two hydrogen atoms approach one another, the valence electron from one atom begins to “feel” the positive force from the other nucleus and vice versa. The electronegativity of the two H atoms is the same; therefore, they each pull on the electrons with the same force. Each nucleus is not strong enough to pull the other’s electron away, nor will it give up its own. The atoms continue to approach each other until the electrons orbit both nuclei. The electrons, which were once single valence electrons to individual nuclei, are now valence electrons to both nuclei; they are co-valence, and a covalent bond is created. Sharing electrons has satisfied the octets of both nuclei and the H2 molecule is more stable than the individual hydrogen atoms alone. Covalent compounds exist as molecules and therefore have molecular formulas. They are easily distinguished from ionic compounds because no metal is present in the chemical formula. The models of H2 and NaCl represent extremes in chemical bonding and, in truth, most chemical bonds possess characteristics of both. Different elements have different electronegativities; therefore, no two elements on the periodic table have the same “desire for electrons.” In a covalent bond between two different nonmetals, the atoms will not pull on the electrons with equal force. The tug of war will be won by the more electronegative element and will result in a slight distortion of the electron’s path around the two nuclei. The shared electrons are pulled toward the more electronegative element, creating a region of slight negative charge. As a result, the region toward the less electronegative element will be slightly positive. The difference in electronegativity is not sufficient to cause an actual transfer of electrons; it merely creates a distorted path resulting in more electron density around the more electronegative element. This is called a polar covalent bond and is very similar to a weak bar magnet.
3.2.3
Polar Bonds
The term “polar covalent” is very simple to justify. The bond is very similar to a weak bar magnet; it has a “north and south pole,” thus the term “polar.” The bond results from a sharing of electrons, or, more specifically, an unequal sharing, thus the term “covalent.” It is often helpful to associate the common characteristics of a simple magnet with words such as polar, polarity, dipole, and dipole moment. Water contains a particularly common example of bond polarity (Fig. 3.3). Water contains two polar covalent bonds between oxygen and hydrogen. The bonding electrons are not shared equally between the two nuclei and are pulled toward the more electronegative oxygen (oxygen is closer to fluorine). This creates a slightly negative region on the oxygen and a slightly positive region on the hydrogen. The regions are represented above by the Greek letter d (lowercase delta), meaning “slightly.” It is important to note that d+ and d− are not fully developed +1 and −1 charges like those found in ionic bonds. The electronegativity difference between oxygen and hydrogen is not sufficient to cause a complete transfer of electrons. The distribution of the electrons between the two nuclei is simply distorted more toward the oxygen and less toward hydrogen. The result is a polar covalent bond. The unequal sharing of bonding electrons in polar bonds may create polar molecules. The permanent dipoles in polar molecules can form weak bonds between adjacent molecules. These intermolecular bonds (“between molecules”) are noncovalent (no sharing) in nature and may be quite extensive. One type of this interaction is termed hydrogen bonding due to the involvement of polar bonds containing hydrogen.
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3.2.4
3
Molecules
Hydrogen Bonding
A common example of hydrogen bonding is the association of water molecules in solution. The slightly negative oxygen on one molecule is weakly attracted to the slightly positive hydrogen on another (Fig. 3.4). Hydrogen bonding is responsible for many of the unusual properties of water, i.e.; high surface tension, high heat capacity, high boiling point, etc.
3.2.5
Multiple Bonds
Covalent bonds may be single, double, or triple, depending on the number of shared electrons. A single bond is formed when only two electrons are shared between the two bonded nuclei. The electrons may be donated from each atom or both from a single atom. Regardless of the source, they are shared equally by each nucleus as octets are achieved in both atoms. Single bonds are generally longer and weaker compared with double or triple bonds. The structures in Fig. 3.5 illustrate single bonds. A pair of electrons (pair of dots) between two symbols represents a single covalent bond. It is also common to use a solid line to represent a covalent bond. The two structures above for methane (CH4) and water (H2O) are different representations of the same molecule. In methane, four pairs of electrons (or the four solid lines) represent the single covalent bonds formed between one carbon and four hydrogen atoms. The same is true for water, two pairs of electrons (or two solid lines) between oxygen and both hydrogen atoms illustrate the bonding arrangement. The remaining electron pairs on oxygen are termed nonbonding pairs; they are not located between two nuclei and therefore do not participate in chemical bonding. Double bonds are formed when four electrons are shared between two combining atoms. Double bonds are shorter and stronger than single bonds and examples are found in oxygen (O2) and carbon dioxide (CO2) (Fig. 3.6).
Fig. 3.4 Hydrogen bonding is a weak, noncovalent interaction between adjacent water molecules. Each molecule is capable of forming four intermolecular bonds: one at each hydrogen and one at each nonbonding electron pair on oxygen. The intermolecular bond length varies with the physical state of water.
Fig. 3.5 Covalent bonds are commonly illustrated using dots (electrons) or lines. The use of lines provides insight into molecular geometry with each line representing a pair of bonding electrons.
Fig. 3.6 Two atoms can share more than one pair of electrons to achieve an octet for each. A double bond results when two pairs are shared. The number of atoms with the capacity to form double bonds is small and generally limited to carbon (C), nitrogen (N), oxygen (O), sulfur (S), and phosphorus (P).
3.4
Molar Mass
27
Fig. 3.7 Triple bonds contain the highest density of bonding electrons between two nuclei. The three pairs of shared electrons represent the upper limit on internuclear occupancy. Bonds containing four pairs of shared electrons between two nuclei do not exist (or have yet to be discovered).
Triple bonds are formed when six electrons are shared between two combining atoms. These bonds are the shortest and strongest of the three types and found in compounds such as nitrogen (N2) (Fig. 3.7).
3.3 3.3.1
Predicting Bond Types Nonpolar Covalent Bonds
1. Bonds formed between two nonmetals that are the same element. 2. Diatomic molecules are the only examples of pure nonpolar covalent bonds: H2, N2, O2, F2, Cl2, Br2, and I2. 3. The electrons are symmetrically distributed between the two nuclei and therefore no magnetic “poles” exist in the bond.
3.3.2
Polar Covalent Bonds
1. Bonds formed between two different nonmetals. 2. These bonds have permanent dipoles (poles) because the electrons are not symmetrically distributed between the two nuclei. 3. The more electronegative element (the one closest to fluorine) will bear a slight negative charge, and the less electronegative element will be slightly positive. 4. These bonds have the same properties and characteristics as weak bar magnets.
3.3.3 1. 2. 3. 4.
Weak, intermolecular (between molecules) forces of attraction between molecules containing polar covalent bonds. The polar covalent bonds must contain hydrogen. They are noncovalent (no sharing of electrons) and electrostatic in nature (opposites attract). They bridge adjacent molecules and can influence chemical and physical properties.
3.3.4 1. 2. 3. 4.
Hydrogen Bonds
Ionic Bonds
Bonds formed between metals and nonmetals. There is an actual transfer of electrons resulting in ion formation. They are electrostatic forces of attraction (opposites attract). The strongest ionic bonds are formed between group I and group VII elements.
3.4
Molar Mass
In our study of atoms, it was determined that the molar mass of an element is simply the atomic mass in grams. For compounds, the molar mass is calculated from the formula mass: the sum total of the individual atomic masses of all elements present in the chemical formula. For example, the formula mass of H2O is 18, the sum of the atomic masses of one oxygen (16) and two hydrogens (2). The formula mass of NaCl is 58.45, the sum total of one Na atom (23) and one Cl atom (35.45). The formula mass can have units of amu’s or grams; 18 amu’s of water is the mass of one molecule of water and 18 g of water is the mass of 6.02 × 1023 molecules, or one mole of water. The chemical formula for NaCl contains a metal; it is
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Molecules
therefore an ionic compound and does not exist as a molecule. Although the concept of the mole is consistent, we must use slightly different terminology to describe it: 58.45 amu’s of NaCl represents the mass of one formula unit, whereas 58.45 g represents the mass of 6.02 × 1023 formula units, or one mole of NaCl. Ionic compounds are described in terms of formula units and covalent compounds in terms of molecules. This terminology, although technically correct, can be a source of confusion. But all is not lost, because the molar mass does not distinguish between ionic and covalent compounds; it is simply the formula mass in units of grams.
3.5
Molarity
A solution of saltwater is called a binary solution because it contains only two components – salt and water. In any binary solution, the component present in the greatest amount is termed the solvent, while the component present in the least amount is termed the solute. A solution of saltwater contains water as the solvent and salt as the solute. What quantity of salt is in our solution? Did we dissolve one teaspoon, two, or perhaps three? Often, it is important to know the exact concentration of solute in solution. Molar concentration or molarity (M) is a unit of concentration defined as the number of moles of solute per liter of solution. The molar mass of common table salt is 58.45 g/mol. A 1-M (one molar) salt solution would be prepared by dissolving 58.45 g of table salt in enough water to make one liter of total solution. We do not add one liter of water because a solution contains both the solvent and solute. The solid table salt will take up space in solution, so we add only the amount of water required to make one liter of total solution.
3.6
Chemical Reactions
A chemical reaction is any process that results in a chemical change. Reactions are represented by balanced chemical equations that illustrate the quantitative relationship between starting materials (reactants) and products. Reactants → Products By convention, an arrow separates the two sides of a chemical equation; the reactants are written on the left side and the products on the right. The arrow always points from the reactants to the products and indicates that a reaction has taken place. It may be helpful to interpret the arrow as “react to form” or “forms.” Heating elemental magnesium in the presence of oxygen gas forms solid magnesium oxide. This reaction is represented by the following chemical equation: heat magnesium(solid) + oxygen(gas) ⎯⎯→ magnesiumoxide(solid)
Substituting formulas, we have the chemical equation: heat Mg(s) + O2(g) ⎯⎯ ⎯ → MgO(s)
The law of conservation of mass states that mass (atoms) cannot be created or destroyed during the course of a chemical reaction. Accordingly, all chemical equations must be “mass balanced.” This means that the number and type of each atom on the reactant side of the arrow must equal the number and type on the product side. The above equation is not balanced because there are two oxygen atoms on the reactant side (O2) and only one on the product side (MgO). To balance oxygen, a coefficient of 2 is placed in front of MgO. heat Mg(s) + O2(g) ⎯⎯ ⎯ → 2MgO(s)
The coefficient multiplies the entire chemical formula; therefore, 2 MgO means MgO + MgO, or two Mg atoms and two O atoms. In the process of balancing oxygen, we “unbalanced” Mg, so we must now insert a coefficient of two in front of Mg on the reactant side. heat 2Mg(s) + O 2(g) ⎯⎯ ⎯ → 2MgO(s)
This is the balanced chemical equation for the reaction of elemental magnesium with oxygen. The coefficients required to balance chemical equations are termed stoichiometric coefficients and represent the quantitative relationship between reactants and products. The above equation is “read”: 2 atoms of elemental magnesium react with one molecule of oxygen to produce 2 formula units of magnesium oxide. A coefficient of one is never written, because it is understood that the formula (alone) represents one. As stated previously, all chemical equations must be balanced; however, this does not mean
3.7
Questions
29
that we must always add coefficients. Hydrochloric acid and sodium hydroxide react to form sodium chloride and water. This reaction is represented by the following chemical equation: HCl + NaOH → NaCl + H 2 O Although the elements have switched partners during the reaction, this equation is balanced. Verify that the number of each element on the left is equal to the number on the right. The application of chemical principles to forensic investigation may not always center on the basic concepts of chemistry. For example, the concept of “balanced equations” may be lost in reactions involving the complex structures of drugs and controlled substances. Nonetheless, a sound foundation in the basic principles of chemical reactivity will enhance the understanding of applications in forensic investigation.
3.7 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21.
Questions Describe a nonpolar covalent bond, a polar covalent bond, and an ionic bond. Characterize each of the following as covalent or ionic compounds: CH4, LiBr, CaO, CO2, CCl4, NaCl, and P4O10. Explain the difference between covalent and ionic bonds. Which groups of elements usually form polar covalent bonds? Explain. Which groups of elements usually form ionic bonds? Why? Which elements form nonpolar covalent bonds? Why? Discuss the similarities and differences between atoms and molecules? Explain the difference between valency and valence electrons. What elements can form double bonds? What elements do not form triple bonds? Discuss the similarities and differences between nonpolar covalent and polar covalent bonds? Discuss similarities and differences between ionic and polar covalent bonds. Which elements will never form ionic bonds? Which elements will never form covalent bonds? What type of bond is formed between a metal and a nonmetal? What type of bond is formed between a nonmetal and a nonmetal? What type of compound (ionic or covalent) results from the bonding of four hydrogen atoms to a single carbon atom? Please explain to the jury chemical bonding and the bonding ability of atoms. Describe the “mole concept” to members of the jury and provide examples. Calculate the molar masses of the following compounds: NaCl, CO2, Li2O, H3PO4, KOH, HCl, H2C2O4, and Al2O3. Balance the following chemical equations: HNO3 + KOH → KNO3 + H 2 O BaSO 4 + NaBr → Na 2 SO4 + BaBr2 Li3 PO 4 + MgCl 2 → LiCl + Mg3 (PO 4 )2 AlCl3 + K 2 O → KCl + Al 2 O3
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Organic Chemistry
4.1
Introduction
Historically, organic chemistry was once defined as the study of the structure and function of molecules originating from living organisms. It was once believed that the unexplained differences between organic compounds, those from living organisms, and inorganic compounds, those from mineral sources, were attributed to an unknown “life force” within the organic compounds. In today’s world of science, advancements in research and technology have laid the mythical “life force” to rest. The complex chemical behavior exhibited by organic compounds is now explained in terms of reaction mechanisms, structural analysis, and thermodynamics. It is now possible to synthesize and manipulate organic molecules in a laboratory environment, and with this knowledge has come a modern definition of organic chemistry. Organic chemistry is the study of the properties, structure, and function of compounds containing carbon. Arguably the most complex and mysterious of the specialized areas of chemistry, organic chemistry often requires years of both practical and theoretical study to master. This chapter is designed to provide a basic survey of the concepts and principles of organic chemistry; reactions will be limited to applications in forensics and structural analysis will concentrate on the basic recognition of functional groups. The defining element in organic molecules is clearly carbon; however, it is universally accepted, and common practice, to define them by the obligate presence of both carbon and hydrogen. This does not mean that organic molecules contain only carbon and hydrogen; elements such as nitrogen, oxygen, sulfur, phosphorus, and chlorine may also be present. The study of organic chemistry does not involve the individual study of the vast number of organic compounds, numbering in the hundreds of thousands and quite possibly millions. Instead, organic compounds are divided into broad classes based on the presence of a common structural feature termed a functional group. Functional groups classify the compound and also allow prediction of chemical behavior. For example, all organic compounds containing a double bond belong to a class termed alkenes. The double bond will undergo predictive chemistry that, in most cases, dominates the reactivity of the molecule. Therefore, through the study of the structure and chemical behavior of double bonds, knowledge is gained on an entire class of organic compounds. The study of functional groups is the most effective and efficient approach to the study of organic chemistry.
4.2
Classification of Organic Compounds: Functional Groups
Individuals possess unique characteristics or features that separate them from the general population. These characteristics may classify them into a particular group; for example, Hispanics, Caucasians, African-Americans, and Asians have an identity within a group that is usually based on physical characteristics. Organic molecules also have unique characteristics or features called functional groups. Functional groups are atoms, groups of atoms, or common structural features used to classify organic molecules (Table 4.1). In general, functional groups will react in a unique, predictive manner and this chemical behavior is similar in all compounds containing a specific group. A few functional groups share a common structural feature; aldehydes, ketones, and carboxylic acids, for example, all contain a carbon–oxygen double bond called a carbonyl group. The type of atom or atoms bound to the carbonyl distinguishes them. It is possible, and quite common indeed, to have more than one functional group on a single
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Table 4.1 Common functional groups found in organic molecules Class Alkane
Functional group
IUPAC ending “-ane”
Alkene
“-ene”
Alkyne Alcohol Ketone
“-yne” “-ol” “-one”
Aldehyde
“-al”
Carboxylic acid
“-oic acid”
Ester
Nitro compounds Amines
“-amine”
molecule. In these cases, the molecule will exhibit chemical and physical properties of all groups present. A wide range of functional groups can be found on different types of controlled substances. Underground chemists convert noncontrolled substances into illegal drugs, controlled substances, and designer drugs using functional-group reactivity, often by simply converting one functional group into another.
4.2.1
Alkanes
Alkanes are saturated hydrocarbons with a general formula CnH2n+2. There are three requirements in the definition of an alkane. First, the compound must be saturated; it must contain only carbon–carbon single bonds. Second, it must be a hydrocarbon; contain only the elements carbon and hydrogen. Lastly, the chemical formula must satisfy the general formula for an alkane, CnH2n+2. The names and chemical formulas for the first ten alkanes are shown in Table 4.2 and should be memorized. The names of alkanes always end in “-ane.” If we examine the chemical formulas, we see that each contains only carbon and hydrogen and each satisfies the general formula for an alkane. For example, butane has a chemical formula C4H10. In this case, n = 4 and the general formula requires a number of H’s equal to 2n + 2 or 10. C4H10
CnH2n+2
2(4) + 2 =10
Any hydrocarbon that contains the number of carbons and hydrogens specified by CnH2n+2 will contain only single bonds (are saturated). There are several methods used to represent organic compounds and each has advantages and disadvantages.
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Classification of Organic Compounds: Functional Groups
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Table 4.2 The first ten alkenes Name Methane Ethane Propane Butane Pentane Hexane Heptane Octane Nonane Decane
Chemical formula CH4 C2H6 C3H8 C4H10 C5H12 C6H14 C7H16 C8H18 C9H20 C10H22
The most common are chemical formulas, structural formulas, condensed structural formulas, and skeletal (or line) formula. We are already familiar with chemical formulas; Table 4.2 contains several examples. Generally, these representations are the easiest and most convenient to write, but provide no information on the geometry of the molecule. Structural formulas are a detailed representation of the bonding arrangement of atoms in the compound. Typically, these formulas are the most tedious to draw. Structural formulas for straight-chain alkanes, commonly termed n-alkanes (n for normal), are drawn by connecting all the carbon atoms in a straight line using single bonds (single lines). The tetravalency (4-bonds) of carbon is maintained using hydrogen. This means that each carbon will have four total bonds (lines) and the bonds other than carbon–carbon bonds will be to hydrogen. The procedure for drawing the structural formula for butane, chemical formula C4H10, is given below. First, draw four carbons in a straight, continuous chain connected by single lines (the single bonds).
Diagram 4.1
Next, maintain the tetravalency of carbon by ensuring all carbons have a total of four lines (bonds).
Diagram 4.2
Lastly, insert hydrogens at the end of each line (vacant bonds) to obtain the structural formula for butane. Verify the structure contains the number of carbons and hydrogens specified in the chemical formula for butane, C4H10.
Diagram 4.3
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Organic Chemistry
A condensed structural formula can be easily obtained from the structural formula.
Diagram 4.4
When condensed structural formulas are used, it is understood that hydrogens are bound to the carbons they follow in the chain. Skeletal (or line) formulas for n-alkanes show only the carbon–carbon bonds, but not carbon or hydrogen atoms. These structures illustrate an overall molecular geometry by showing realistic carbon–carbon bond angles. Butane is shown below using this method.
Diagram 4.5
In skeletal formulas, it is understood that carbons reside at both terminals (ends) and at each vertex, the points where the line changes direction (the peaks and valleys). There are enough hydrogens at each carbon to fill its tetravalency, but they are never written in this method. Skeletal formulas are the method of choice used to represent most complex organic compounds and will be used extensively in the following chapters. The next time you need a prescription, open the insert material and you will commonly see the structure of the drug represented using this method. Slight variations to structural formulas can provide a three-dimensional view of the molecule. This stereochemistry is illustrated through the use of wedges; a solid wedge represents a bond extending out toward the viewer, and a dashed wedge represents a bond extending back from the viewer. Methane, for example, has a chemical formula of CH4 and a tetrahedral geometry. A typical structural formula is shown below.
Diagram 4.6
At first glance, the structure of methane appears to be flat, with all bonds in the same plane with apparent H–C–H bond angles of 90°. The use of wedges adds depth to the structure and illustrates a more realistic view of the actual tetrahedral geometry which contains H–C–H bond angles of 109.5°.
Diagram 4.7
4.2
Classification of Organic Compounds: Functional Groups
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The use of wedges to show stereochemistry (a three-dimensional view) is required in complex molecules where an illustration of bond depth is essential.
4.2.1.1 Naming Alkanes Naming alkanes is a bit more involved than simply memorizing the first ten members, although this is an excellent start. Many organic molecules, including alkanes, contain substituted groups attached to a parent chain. The names of these compounds must incorporate the substituted groups, their location, and the parent chain. The rules for naming organic compounds are determined by an organization called the International Union of Pure and Applied Chemistry (IUPAC). Their goal is to maintain consistency in naming to ensure worldwide recognition of organic compounds. 4.2.1.2 Rules for Naming Alkanes 1. Determine the parent chain – the longest, continuous chain of carbons. 2. Name all substituted groups attached to the parent chain. 3. Number the parent chain in such a manner that the lowest number falls on the carbon containing the first substitution. 4. Locate the substituted groups on the parent chain using the carbon number containing the group. In cases with multiple substitutions, alphabetize the groups. 5. Name the alkane. Examples:
Diagram 4.8
The above structures are different representations of the same compound. 1. Verify the longest, continuous chain of carbons is five; the parent chain is pentane and this compound is a pentane derivative (C5 from our table of alkanes). 2. Verify only one substituted group, a chlorine. 3. Numbering the chain left to right places the chlorine at carbon #4, numbering right to left places it at carbon #2. We chose right to left because it puts the lowest number on the first (and only) point of substitution. 4. This compound is 2-chloropentane, a 5-carbon parent (pentane) containing a chlorine atom at carbon #2. A hyphen always separates the carbon number from the substituted group attached at the carbon. Note the name of the substituted group is not its elemental name; chlorine (Cl) becomes chloro when it is attached to a parent chain. Group VIIA elements (halogens) are commonly found in organic compounds and their names as substituted groups are worth memorizing: F-fluoro, Cl-chloro, Br-bromo, and I-iodo. Verify the names of the following compounds:
Diagram 4.9
The above examples illustrate a few important principles in naming – alphabetizing takes priority over numbering, carbons containing substituted groups are not arranged in any particular ascending or descending order, and hyphens always separate substituted groups when multiple substitutions are present.
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Organic Chemistry
It is quite common to have small chain alkanes substituted on larger parent chains. In these cases, a single hydrogen atom must be removed from the shorter chain to create a point of attachment. The removal of a single hydrogen from an alkane creates an alkyl group. The names of alkyl groups end in “yl” and are determined by dropping the “ane” ending from the alkane name and adding the suffix “yl.” Alkyl groups are represented using the letter “R” in cases requiring a “generic” hydrocarbon; accordingly, alkyl groups are termed R-groups. This terminology will be used extensively in our study of functional groups.
Diagram 4.10
Diagram 4.11
In naming, alkyl groups are treated simply as substituted groups.
Diagram 4.12
Physical properties of alkanes, such as boiling points and melting points, are affected by the chain length or size of the alkane. In general, alkane boiling points and melting points increase with increasing chain length. For example, methane (CH4) has a boiling point of −164°C and a melting point of −182°C, while decane (C10H22) has a boiling point of 174°C and a melting point of −30°C.
4.2.1.3 Cycloalkanes Alkanes can also exist in closed ring structures called cycloalkanes. They are hydrocarbons that have a general formula CnH2n. Notice the number of hydrogens specified in the general formula is two less than that required for alkanes (CnH2n+2). Hydrocarbons containing a number of hydrogens less than the number required by its alkane counterpart are termed unsaturated. For this reason, cycloalkanes are classified as unsaturated compounds. Cycloalkanes are named using the prefix “cyclo” attached to the alkane name.
Diagram 4.13
4.2
Classification of Organic Compounds: Functional Groups
37
The number of carbons contained in the above rings is six. The alkane containing six carbons is hexane and requires 14 hydrogens (CnH2n+2, where n = 6), but the ring structures show a formula of C6H12 (CnH2n, where n = 6). The above structures are different representations of cyclohexane, an unsaturated compound. Cycloalkanes are almost exclusively represented using skeletal formulas and, in general, have the same chemical and physical properties as alkanes.
4.2.2
Alkenes
Diagram 4.14
Alkenes are unsaturated hydrocarbons with a general formula CnH2n. Note the general formula for alkenes is identical to that of cycloalkanes. There are similarities between alkane and alkene definitions; both are hydrocarbons and the number of carbon and hydrogen atoms must satisfy a general formula. The major difference, aside from the slightly different general formulas, is alkenes must be unsaturated; that is, they must contain at least one carbon–carbon double bond. It is worth noting that carbon–carbon double bonds are often termed points of unsaturation. Any compound that is an unsaturated hydrocarbon satisfying the general formula CnH2n and is not a ring belongs to the alkene class of organic compounds. The names and chemical formulas for the first nine alkenes are shown in Table 4.3. Why nine and not ten? You must have at least two carbons to form a double bond. Alkene names end in “-ene,” indicating the presence of at least one carbon–carbon double bond in the compound. Verify that the chemical formulas in Table 4.3 contain only carbon and hydrogen and each satisfies the general formula CnH2n. Methods for drawing structural formulas, condensed structural formulas, and skeletal structures for alkenes are similar to those used for alkanes. The notable difference is the use of a “double line” to represent the double bond.
Diagram 4.15
Table 4.3 The first nine alkenes Name Ethene Propene Butene Pentene Hexene Heptene Octene Nonene Decene
Chemical formula C2H4 C3H6 C4H8 C5H10 C6H12 C7H14 C8H16 C9H18 C10H20
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Organic Chemistry
The location of the double bond must be specified when naming alkenes containing four or more carbons. In these cases, the number of the first carbon involved in the double bond is included in the name. Consider the following skeletal formulas for butene.
Diagram 4.16
Verify the number of carbons in each of the above structures is four. The alkane containing four carbons is butane (C4H10), but the above structures are both butenes because a double bond is present in each. The location of the double bond is clearly different and the carbons in the parent chain are always numbered in a manner that places the lowest number on the first carbon contained in the double bond. In the first example above, we can number the carbons left to right or right to left. If we number left to right, we find the double bond begins at carbon #1, but numbering right to left, we find the double bond begins at carbon #3. The chain is numbered left to right. This is 1-butene (not 3-butene); indicating the “ene” (double bond) begins at carbon #1. The other structure is 2-butene using similar reasoning. Can you justify the following names?
Diagram 4.17
4.2.2.1 Cycloalkenes Alkenes can also exist in ring structures called cycloalkenes. The chemical formulas for cycloalkenes vary according to the number of double bonds present in the structure.
Diagram 4.18
Recall that skeletal formulas contain carbons at each vertex (change of direction) and the tetravalency of carbon is maintained with bonds to hydrogen that are never shown. Each of the above cycloalkenes contains five carbons. Next, determine the number of bonds to hydrogen required to total four bonds on each carbon. Verify the above formulas for each structure. Naming cycloalkenes also (like cycloalkanes) requires the addition of the prefix “cyclo” to the parent alkene name.
Diagram 4.19
It is not necessary to locate the double bond in cycloalkenes containing only one point of unsaturation (double bond). However, if more than one double bond is present, the locations of all double bonds are specified using the first carbon in each carbon–carbon double bond. You may start with any carbon–carbon double in the structure, but you must number in the direction of the double bond and in such a way that the lowest number falls on the first carbon of the next double bond. In addition, the prefixes, di, tri, etc., must be added to the “ene” portion of the name.
4.2
Classification of Organic Compounds: Functional Groups
39
Diagram 4.20
Many controlled substances contain cycloalkenes or cycloalkene derivatives. Cyclopentene, for example, is frequently used in clandestine laboratories to produce phencyclidine (PCP).
4.2.3
Alkynes
Diagram 4.21
Alkynes are unsaturated hydrocarbons with a general formula CnH2n−2. This class of organic compound contains at least one carbon–carbon triple bond. Notice the general formula specifies four less Hs than that required for alkanes (CnH2n+2). The loss of two Hs from an alkane produced an additional bond (one point of unsaturation) and the alkene class. The loss of four Hs from an alkane produces two additional bonds (two points of unsaturation) and the alkynes. We may conclude that alkanes are “saturated” with hydrogens, and the loss of any hydrogens from an alkane produces an “unsaturated” compound at a rate of two Hs per additional bond (point of unsaturation). The names and chemical formulas for the first nine alkynes are shown in Table 4.4. Alkyne names end in “-yne” with one notable exception: C2H2 is rarely named ethyne, it is almost exclusively called acetylene. Despite the “ene” ending in acetylene, it is not an alkene and does not contain a carbon–carbon double bond.
Diagram 4.22
Notice the structure of acetylene is linear (a straight line). This is the geometry of all carbon–carbon triple bonds and results from the orientation of the combining orbitals on the carbons involved in the triple bond, a process termed hybridization. Methods for drawing structural formulas, condensed structural formulas, and skeletal structures for alkynes are similar to those used for alkanes and alkenes. The triple bond is represented using a “triple line.”
Table 4.4 The first nine alkynes Name Ethyne Propyne Butyne Pentyne Hexyne Heptyne Octyne Nonyne Decyne
Chemical formula C2H2 C3H4 C4H6 C5H8 C6H10 C7H12 C8H14 C9H16 C10H18
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Organic Chemistry
Diagram 4.23
The location of the triple bond must be specified when naming alkynes containing four or more carbons. Verify the names for each structure below.
Diagram 4.24
4.2.3.1 Cycloalkynes Cycloalkynes containing eight or more carbons are common. The linear geometry of carbon–carbon triple bonds introduces severe strain in small rings where bond angles deviate significantly from 180°. As ring size increases, the bond angles between adjacent carbons approach the favorable linear geometry of alkynes.
Diagram 4.25
4.2.4
Aromatic Compounds
Benzene is the common name for 1,3,5-cyclohexatriene, a unique member of the cycloalkene class. It is a flat ring with a chemical formula of C6H6.
Diagram 4.26
Benzene is unusually stable and does not undergo reactions typical of alkenes. Surprisingly, structural analysis of benzene reveals six identical carbon–carbon bonds, not three carbon–carbon double bonds and three carbon–carbon single bonds as shown in the above structural formulas. The distance between adjacent carbons in benzene is longer than a carbon–carbon double bond, but shorter than a carbon–carbon single bond; in fact, the distance is almost exactly midway between the two. For this reason, benzene is frequently represented as a hexagon with an inscribed circle representing the six identical carbon– carbon “one and a half” bonds.
4.2
Classification of Organic Compounds: Functional Groups
41
Diagram 4.27
The unusual stability exhibited by benzene is attributed to the fact that: It is a ring It is planar (flat) It is conjugated It satisfies the Huckel rule A detailed explanation of the above conditions is beyond the scope of this text; however, any compound that satisfies the above will be aromatic and exhibit aromatic character. Benzene and derivatives of benzene are aromatic compounds, a class of organic molecules marked by unusual stability. In addition, aromatic compounds frequently have strong, pungent (often unpleasant) odors, a characteristic indicated by the term “aromatic,” which is derived from aroma (to smell). Naphthalene, for example, is an aromatic compound used in the production of mothballs and is responsible for their distinct odor. Structural formulas of some aromatic compounds are shown below; notice the presence of benzene or “benzene-like” structures. 1. 2. 3. 4.
Diagram 4.28
Diagram 4.29
4.2.5
Alcohols
Diagram 4.30
Alcohols are organic compounds that contain the hydroxyl functional group (–OH). The names of alcohols end in “-ol,” indicating the presence of the hydroxyl group, for example, methanol (fuel), ethanol (drinking alcohol), and isopropanol (rubbing alcohol). When naming alcohols, the “-e” is dropped from the alkane containing the “–OH” group and replaced with the suffix “-ol.”
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Organic Chemistry
Diagram 4.31
Justify the names above; for example, in propanol, the hydroxyl group is attached to a three-carbon chain (propane), dropping the “-e” and adding “ol” gives propanol. The location of the hydroxyl group must be specified in alcohols containing four or more carbons. The chain is numbered in a manner that places the lowest number on the carbon containing the –OH group.
Diagram 4.32
The above examples both have an –OH attached to a four-carbon chain. The location of the –OH must be reflected in the name. Can you justify each name above? (Hint: the chains, in both cases, must be numbered right to left.) Alcohol derivatives of propane represent an interesting case in which it is possible to name a single structure using two different names. The structures below are almost exclusively identified using the names under each, but the alternative names in parenthesis are also technically correct. OH
OH
OH
OH
CH3 — CH2 — CH2 — OH
CH3 — CH — CH3
CH2 — CH — CH2
Propanol (1-propanol)
Isopropanol (2-propanol)
Glycerol (1,2,3-propanetriol)
Diagram 4.33
Alcohols can also be classified based on the number of carbons attached to the carbon containing the hydroxyl group. A primary alcohol (1°) has one carbon attached to the carbon containing the hydroxyl group, secondary alcohols (2°) have two carbons, and tertiary alcohols (3°) have three. Identify the carbon containing the OH group in each example below. Determine the number of carbons bound to the OH containing carbon to verify each classification.
Diagram 4.34
4.2
Classification of Organic Compounds: Functional Groups
43
Alcohols are polar organic solvents that exist in liquid form at room temperature (25°C). The solubility of alcohols (ability to mix) in other polar liquids (e.g., water) is dependent on the size of the carbon chain containing the –OH group. As the size of the chain increases, the alcohol tends to exhibit the nonpolar character of the hydrocarbon chain. This translates to a reduced solubility in water. Small-chain alcohols such as methanol, ethanol, and propanol will readily mix with water, while butanol, pentanol, and hexanol are slightly soluble. Octanol and larger alcohols are insoluble and form two layers when mixed with water. Alcohols do not exhibit acidic or basic character and generally have a pH comparable to water. They are moderately toxic if ingested, a characteristic exhibited by the most common member, ethanol (drinking alcohol). Methanol, ethanol, and isopropanol are common solvents used in the clandestine manufacturing of controlled substances (Fig. 4.1). Designer drugs are produced through the chemical modification of illegal drugs or controlled substances. Designer drug manufacturing distinguishes itself from other types of drug manufacturing by requiring starting material that is already regulated by law. In some cases, production may be as simple as removing an –OH group. For example, bufotenine and psilocin are naturally occurring positional isomers that differ only in the location of the hydroxyl group. Both belong to the family of hallucinogenic drugs derived from dimethyltryptamine (DMT).
Diagram 4.35
Addition of a hydroxyl group at carbon four of the benzene ring on DMT produces psilocin, a hallucinogenic drug. Relocation of the hydroxyl group from carbon four on psilocin to carbon five generates bufotenine, another hallucinogenic drug.
Fig. 4.1 Examples of packaged denatured alcohols that are used as solvents in manufacturing controlled substances.
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Organic Chemistry
Diagram 4.36
Bufotenine, psilocin, and DMT are derivatives of the indole family of organic compounds and are easily recognized by the characteristic fused five- and six-membered ring systems. It is often helpful to recognize fused ring systems that frequently occur in different types of organic compounds. Most steroids, for example, are immediately identified by the presence of the classical fused ring system in cholesterol, a common precursor in their production. Ephedrine and pseudoephedrine also contain the hydroxyl functional group. They differ only in the special orientation of the –OH group and both are used to treat symptoms of hay fever, asthma, and nasal congestion. Unfortunately, they are also precursors in the production of methamphetamine, a controlled substance that stimulates the central nervous system. Ephedrine and pseudoephedrine are not currently controlled, but their distribution and sale are closely regulated. Recall the wedge convention; a solid wedge indicates a bond extending out toward the viewer and a dashed wedge indicates a bond extending back from the viewer.
Diagram 4.37
Pseudoephedrine is one of the most frequently used precursors in the illicit production of methamphetamine. The synthetic reaction is called a reduction reaction and results in the loss of the hydroxyl group.
Diagram 4.38
4.2.6
Ketones
Diagram 4.39
Ketones are organic compounds that contain a carbon–oxygen double bond. This structural feature is called a carbonyl group (R–CO–R).
4.2
Classification of Organic Compounds: Functional Groups
45
Diagram 4.40
The names of ketones end in “-one,” indicating the presence of the carbonyl group, i.e.; acetone, butanone, and pentanone. When naming ketones, the “-e” is dropped from the alkane containing the carbonyl group and replaced with the suffix “-one.” The location of the carbonyl group must be specified in ketones containing five or more carbons. The chain is numbered in a manner that places the lowest number on the carbon containing the double bond to oxygen. It is worth noting that the carbonyl group can never appear on the end carbons (terminal carbons) in ketones. Carbonyl groups on terminal carbons will be covered shortly in our study of aldehydes and carboxylic acids.
Diagram 4.41
Notice that the carbonyl carbons are not labeled in the top two structures above (see below for explanation) and the bottom two examples are complete skeletal formulas. Skeletal formulas will be used extensively in our study of forensic chemistry. We must begin to develop a familiarity with “interpreting” structures presented in this manner. Can you justify the name of each ketone above? Acetone is the smallest member of the ketone family. A carbonyl group cannot appear on terminal carbons in the ketone class and a two-carbon chain would require the carbonyl to appear at a terminal carbon. Why is the second structure above butanone and not 2-butanone? In your mind, move the carbonyl to the other interior carbon and verify that it is the same structure. In general, ketones are toxic and possess very strong, pungent odors. They are soluble in water as well as a variety of organic solvents. The carbonyl group is polar and therefore capable of hydrogen bonding in water. Similar to alcohols, ketone solubility depends on the length of the hydrocarbon chain. Acetone is a very common organic solvent that is used extensively in clandestine labs. It is generally the solvent of choice for the “icing” stage of methamphetamine production. Ketones are very prominent in all stages of drug production representing solvents, precursors, and even controlled substances. Phenyl-2-propanone (P2P) is a precursor to methamphetamine. Barbiturates contain multiple carbonyl groups, ie; phenobarbital. Cathinone and methcathinone are well-known controlled substances containing ketone functional groups.
Diagram 4.42
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Organic Chemistry
Diagram 4.43
Unfortunately, the chemical procedures used in the clandestine production of drugs are surprisingly simple and generally involve converting one functional group into another. In some cases, the ease with which this can be accomplished would astound, and perhaps frighten, any law-abiding citizen. Pseudoephedrine, a closely regulated but easily attainable drug, can be converted to methcathinone (ephedrone “Jeff”) under relatively mild conditions using readily available chemicals.
Diagram 4.44
4.2.7
Aldehydes
Diagram 4.45
Aldehydes are organic compounds that contain a carbonyl group bound to at least one hydrogen atom. These bonding conditions can only be satisfied if the carbonyl is located on a terminal carbon. In the aldehyde arrangement, a carbon must contain two bonds to oxygen (carbonyl carbon) and a single bond to hydrogen. This leaves only one vacant bonding position.
Diagram 4.46
The names of aldehydes end in “-al,” indicating the presence of the aldehyde group, i.e.; propanal, butanal, and pentanal. When naming aldehydes, the “-e” is dropped from the alkane containing the aldehyde group and replaced with the suffix “-al.” The chain is numbered from the aldehyde group that is always located on the first carbon. Unlike other functional groups, the location of the aldehyde group is not included in the name because it can only appear at carbon #1.
4.2
Classification of Organic Compounds: Functional Groups
47
Diagram 4.47
A common mistake in aldehyde naming is the omission of the carbonyl carbon when determining chain length. The carbonyl carbon is always the first carbon in the parent chain and must be included. The chemical and physical properties of aldehydes are similar to those of ketones. This comes as no surprise given the structural similarities between the two functional groups. In general, aldehydes are toxic and possess very strong, pungent odors. They are soluble in both water and organic solvents, depending on the length of the hydrocarbon chain. The polar carbonyl group in aldehydes is capable of hydrogen bonding in water. Aldehyde functional groups are not usually found in the structures of illegal drugs or controlled substances; however, this group plays an important role in their identification. For example, formaldehyde is used in the Marquis test for initial screening of opium and phenethylamine families of controlled substances. Acetaldehyde is used in chemical-screening tests to detect marijuana, as well as screening secondary amines containing phenethylamine.
4.2.8
Carboxylic Acids
Diagram 4.48
Carboxylic acids are organic molecules characterized by the presence of a carbon containing both a double bond to oxygen (carbonyl group) and a single bond to a hydroxyl group (–OH). They represent a diverse class of organic molecules that can act as both acids (donate H+) and bases (accept H+), depending on the pH of the solution.
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Organic Chemistry
Diagram 4.49
The names of carboxylic acids end in “-oic acid,” indicating the presence of the carboxyl group, i.e.; propanoic acid, butanoic acid, and pentanoic acid. When naming carboxylic acids, the “-e” is dropped from the alkane containing the carboxyl group and replaced with “-oic acid.” The chain is numbered from the carboxylic acid group which is always located on the first carbon. Again, the location of the functional group is not included in the name.
Diagram 4.50
Several members of this class are widely known by their common names and, unlike other functional groups, they can exist in two forms. The forms are distinguished by name and differ only in the presence or absence of hydrogen on the hydroxyl group. In general, the protinated forms (H is present) end in “-ic acid” and the deprotinated forms (H is absent) end in “-ate.” This practice is limited to common names and is not routinely applied to systematic naming. Several examples are provided below.
Diagram 4.51
Diagram 4.52
Diagram 4.53
4.2
Classification of Organic Compounds: Functional Groups
49
Diagram 4.54
Many controlled substances contain this functional group. The most famous is gamma-hydroxybutyric acid (GHB), which gained notoriety by its street name “the date rape drug.”
Diagram 4.55
4.2.9
Esters
Diagram 4.56
Esters are organic compounds containing a carbonyl bound to an alkoxy group (–OR). The alkoxy group is oxygen bound to a hydrocarbon chain of varying length.
Diagram 4.57
The systematic naming of esters, although important, is not relevant to applications in forensic chemistry and therefore will not be discussed. Although some of the most widely recognizable drugs contain ester groups, they are not named as ester derivatives. Nonetheless, it is important to recognize this functional group as part of the structure of various drugs and other controlled substances. The consistency with which ester groups are found with amino groups in some of the most dangerous drugs in existence is somewhat surprising.
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Organic Chemistry
Diagram 4.58
Diagram 4.59
4.2.10 Nitro Compounds
Diagram 4.60
Nitro compounds are distinguished by the presence of the highly polar nitro functional group – a nitrogen atom bound to two oxygen atoms (–NO2). The chemical formula shows that the group does not carry an overall net charge; however, the structural formula reveals the highly polar nature of this functional group.
Diagram 4.61
Nitro groups are not typically found in the structures of illegal drugs; however, they are an important part of forensic investigation. Nitro compounds are primarily used to test and detect a variety of functional groups frequently found in illegal drugs and controlled substances (Fig. 4.2).
4.2
Classification of Organic Compounds: Functional Groups
51
Fig. 4.2 Examples of nitro compounds used to detect a number of groups found in illegal drugs and controlled substances. (Left) Cobalt (1) nitrate is used to detect tertiary amines. (Center) Sodium nitroferricyanide is used to detect secondary amines; (Right) Silver nitrate is used to detect acids.
4.2.11
Amines
Diagram 4.62
Amines are organic compounds that contain an amino group – a nitrogen bound to one, two, or three hydrocarbon groups. All amines are organic derivatives of ammonia (NH3) formed by replacing hydrogen atoms with hydrocarbons. Amines are classified as primary (1°), secondary (2°), or tertiary (3°), depending on the number of hydrocarbon substitutions;
Diagram 4.63
52
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Organic Chemistry
primary amines contain one hydrocarbon substitution, secondary amines contain two substitutions, and tertiary amines contain three. Although several methods are used to name compounds in this class, it is common for the names to incorporate the substituted groups and end with the suffix “-amine.” It is important to note that no constraints are placed on the hydrocarbon substitutions; they may be identical, different, chains, rings, etc. In the field of forensic investigation, amines are arguably the most important class of organic compounds. Amino groups are found in the structures of some of the most destructive and addictive substances known. Heroin, cocaine, phencyclidine (PCP), lysergic acid diethylamide (LSD), and morphine are tertiary amines, as is the poison strychnine. Methamphetamine, ephedrine, pseudoephedrine, and ketamine are secondary amines. Amphetamine, tryptamine, and 3,4-methylenedioxyamphetamine (MDA) are examples of primary amines. The high occurrence of amino groups in the structures of drugs and controlled substances has led to the development of a variety of tests and screening methods to detect amines.
4.2.11.1
Primary Amines
Diagram 4.64
Diagram 4.65
4.2.11.2
Secondary Amines
Diagram 4.66
In general, chemical screening tests for secondary amines are very reliable. There are notable exceptions with ketamine, ephedrine, and pseudoephedrine where intramolecular (within molecule) interactions “mask” the secondary amine functional group. The hydroxyl group is the culprit with ephedrine and pseudoephedrine. The hydrogen atom on hydroxyl forms a hydrogen bond with the amino nitrogen and disguises the secondary amine. Pseudoephedrine is shown below for illustration.
4.2
Classification of Organic Compounds: Functional Groups
53
Diagram 4.67
Ketamine is slightly more complicated; it is a secondary amine that tests positive using tertiary amine chemical screening. This results from an intermolecular rearrangement involving the chlorine atom in ketamine.
4.2.11.3
Tertiary Amines
Diagram 4.68
Diagram 4.69
O CH3 N
N H
N
N H Pheneyelidine (PCP)
Diagram 4.70
Lysergic acid diethylamide (LSD)
54
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Organic Chemistry
LSD does not test positive using tertiary amine chemical screening. This behavior is the result of two factors: intermolecular rearrangements and structural symmetry of the amino group. All is not lost, because LSD does test positive using Van Urk’s reagents. See Chap. 7, for more information.
4.3
Methyl Group (–CH3)
The methyl group is not a functional group and is not used to classify organic molecules. This group does not represent a dominant reactive site that may be used to predict chemical behavior. However, the importance of methyl groups in the production of designer drugs and controlled substances warrants consideration. In some cases, there may be extreme differences in the biological activity of two structures differing only in the presence or absence of a single methyl group. Under these circumstances, it may be tempting to label the methyl group as a functional group. A close examination of the structure suggests that it may be more appropriate to attribute the observed differences in activity to a modification of existing functional groups. For example, amphetamine and methamphetamine differ only in the added methyl group seen in methamphetamine. The difference in activity between the two is more likely the result of the conversion of a primary amine into a secondary amine, and not based on the reactivity of the added methyl group alone.
Diagram 4.71
It is also possible to produce illegal substances by simply changing the position of a methyl group on a single molecule. DMT and a,N-DMT (a,N-dimethyltryptamine) differ only in the position of a single methyl group. Molecules that exhibit this relationship are termed positional isomers. The production of positional isomers is often done to avoid legal restrictions or regulations imposed on one of the isomers and the conversion is generally a simple task.
CH3 CH2
CH3 CH2
N CH2
CH3
N CH
H
CH3 N H DMT (N,N-dimethyltryptamine)
N H α,N-DMT (α,N-dimethyltryptamine)
Diagram 4.72
4.4
Compounds Containing Multiple Functional Groups
Functional groups are atoms, groups of atoms, or structural features that undergo predictive chemistry. The chemical behavior of a specific functional group is generally used to detect, identify, and classify both legal and illegal chemicals. A vast majority of drugs, designer drugs, and controlled substances contain multiple functional groups. Although their classification is usually based on one of the groups, all functional groups have some influence on the reactivity of the compound. For this reason, a variety of tests are usually required to conclusively identify a particular substance. Examples of compounds containing multiple functional groups are shown below.
4.5
Chirality
55
Diagram 4.73
Diagram 4.74
Lysergic acid diethylamide (LSD) is named as an amide derivative, a functional group we did not discuss in our study of organic chemistry.
4.5
Chirality
Take a moment and compare your right hand to your left. They are virtually identical in most respects, but a right glove will not fit on your left hand. Your hands are mirror images that are not superimposable on one another, a fact you may have never considered, nor had cause to, until now. This property of “handedness,” or chirality (chiral: Greek-“handed”), is characteristic of organic compounds containing chiral carbons – any carbon bound to four different groups. The nonsuperimposable mirror images of chiral molecules are stereoisomers called enantiomers. Stereoisomers have the same chemical formula but differ in the spatial arrangement of atoms. Enantiomers have almost identical physical and chemical properties; for example, same melting points, boiling points, and solubility. Your hands, which themselves are enantiomers, are clearly different from one another; by analogy, there must be a difference that distinguishes the enantiomers of chiral molecules. The search for this difference leads us to an unlikely candidate, the electromagnetic spectrum, or light. Enantiomers exhibit optical activity by rotating plane-polarized light in equal, but opposite directions. One enantiomer will rotate light clockwise (right) and is said to be dextrorotary (or also dextrorotatory), whereas the other will rotate light counterclockwise (left) and is referred to as levorotary (or also levorotatory). The direction of rotation is indicated in the names of optically active molecules using a “(d)” or “(+)” for dextrorotary, for example, (d)-morphine or (+)-morphine, and “(l)” or “(–)” for levorotary, for example, (l)-morphine or (–)-morphine. The optical activity of a specific molecule is determined using a polarimeter to measure the rotation of polarized light. The R/S convention is a quick, reliable method used to distinguish enantiomers without the necessity of polarimetry experiments. The details of this method are beyond the scope of this text; however, a basic overview is presented because this convention has relevance in our study of forensic chemistry. The four different groups attached to chiral carbons are assigned priorities using the Cahn–Ingold–Prelog system (not discussed). The structure is oriented in a manner that allows the viewer to look down the carbon bond containing the lowest priority group, usually a carbon–hydrogen bond. The remaining groups are arranged in a circular configuration facing the viewer. One simply counts the remaining groups 1, 2, 3; if counting is in a clockwise direction, the R-isomer is present (rectus: Latin-“right”). If counting is counterclockwise, the S-isomer is present (sinister: Latin-“left”). It is worth noting that the R/S designation does not indicate optical rotation; it is simply a quick, easy method used to differentiate enantiomers. For example, (S)-glyceraldehyde is levorotary whereas (S)-alanine is dextrorotary. An understanding that optically active isomers exist, and the basic recognition of conventions used to differentiate them, is far more valuable than knowing the exact direction of rotation, which is usually of little consequence.
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Organic Chemistry
A sound foundation in organic chemistry is an absolute necessity in forensic investigation. Forensic scientists must be skilled in the interpretation of complex chemical procedures and results. In addition, they must be able to communicate this knowledge to members of a jury using common terminology. This ability is specific to forensics and generally not found in other areas of science. It is developed through knowledge, training, and experience and distinguishes forensic scientists as some of the most versatile and diverse in the scientific community.
4.6 1. 2. 3. 4. 5. 6.
7. 8. 9.
10. 11. 12.
Questions Define organic chemistry. Please define the term functional group to members of the jury. Name the first ten alkanes with their chemical formulas. Draw the structural formula and condensed structural formula for heptane. Draw methane using the wedge convention. Draw the following: (a) 2,2-dichlorohexane (b) 1,2-dibromo-4-fluorononane (c) 2,2,3-trimethyl-3-chloroheptane (d) Cyclopentane Name the first four alkenes. Draw the structures with a chemical formula C4H8 (there are three), and name each. Draw the following: (a) 2-hexene (b) 3-chloro-2-heptene (c) Cyclohexene Explain why acetylene is not a member of the alkene class. Define aromatic character. Name the following: CH3
Cl
Cl
OH
Br
Cl
13. Draw the following alcohols and classify each as primary, secondary, or tertiary. (a) Isopropanol (b) 2-methyl-2-propanol (c) 1-hexanol (d) 3-heptanol 14. Discuss alcohol solubility in water. 15. Why is acetone the smallest member of the ketone class? 16. Draw 3-hexanone and butanone. 17. Name the following: O O
O H H
H
H CH3
18. Draw the following: (a) 2-chlorobutanoic acid (b) Hexanoic acid (c) Acetic acid 19. Classify the following amines as primary, secondary, or tertiary. (a) Amphetamine
Suggested Reading
(b) 3,4-methylenedioxamphetamine (c) PCP (d) Cocaine (e) Ketamine (f) Ephedrine 20. Identify all functional groups in the following: (a) Heroine (b) LSD (c) Ephedrine (d) Cocaine (e) PCP
Suggested Reading Jones, M. Organic Chemistry, 3rd ed.;W.W. Norton & Company: New York, 2004, (Chapter 21).
57
Part II Tools of Forensic Chemistry
5
Forensic Language
5.1
Defining Drugs
Drugs, narcotics, and controlled substances may be defined as: • Any substance that causes dependency in humans. • Any substance intended for use in the diagnosis, cure, mitigation, treatment, or prevention of disease(s). • Any substance that alters the mind, senses, mood, or thoughts. • Any substance listed in the Official United States Pharmacopeia, the Official Homeopathic Pharmacopeia of the United States, or the Official National Formulary.
5.2
Origin of Drugs (Narcotics)
5.2.1
Natural Drugs
Heroin, cocaine, tetrahydrocannabinol (THC), bufotenine, psilocin, and psilocybin are narcotics derived from either plants or animals. Heroin is extracted from the poppy plant using a relatively simple procedure, and cocaine is easily isolated from coca plants. THC can be extracted from marijuana plants or its effects can be obtained from direct use of the dried plant (i.e., smoking). LSD is extracted from the ergot of rye and psilocin/psilocybin is isolated from mushrooms. Bufotenine is collected from the skin glands of the Bufo toad or from toadstool mushrooms.
5.2.2
Synthetic Drugs
Synthetic drugs are derived from mineral sources using a wide range of chemical processes. Barbiturates (produced from pyrimidine), phenethylamine analogs (except drugs in Khat or peyote plants), and the tryptamine family of drugs represent common examples of synthetic drugs.
5.2.3
Psychotropic Drugs (Mind Altering)
“Excitantia”: Stimulants, such as caffeine and amphetamine “Inebriantia”: Intoxicants, such as ethanol and nitrous oxide “Hypnotica”: Hypnotics, such as methaqualone and mecloqualone “Euphorica”: Analgesics/tranquilizers, such as morphine and heroin “Phantastica”: Hallucinogens, such as psilocyn and mescaline Psycoanaleptique: Cocaine and amphetamine
J.I. Khan et al., Basic Principles of Forensic Chemistry, DOI 10.1007/978-1-59745-437-7_5, © Springer Science+Business Media, LLC 2012
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Psycholeptiques: Morphine and heroin “Entactogens”: MDMA (3,4-methylenedioxymethamphetamine, ecstacy) and MDA (3,4-methylenedioxyamphetamine) Psychodysleptiques: Mescaline and LSD (lysergic acid diethylamide)
5.3
Dependence and Addiction
5.3.1
Physical Dependence
Physical dependency is a condition resulting from chronic drug use that is characterized by the physiological side effects of tolerance and withdrawal. Tolerance is the need to ingest progressively larger amounts of a drug to maintain a desired effect. It is a condition characterized by a marked decrease in both time duration and intensity of analgesia, euphoria, and sedation associated with a specific dosage. Tolerance development is inconsistent and unpredictable; toxic side effects often accompany increased tolerance. Withdrawal is a term used to describe the unfavorable physical symptoms that result if drug use is suddenly stopped or dosage is drastically reduced. Withdrawal symptoms can range from mildly unpleasant to life threatening and their severity depends on a number of factors, i.e.: age, sex, type of drug, frequency and duration of abuse, daily dosage, route of administration, and concurrent abuse of other drugs. In general, short-term narcotics tend to produce shorter, more intense withdrawal symptoms, while longer-acting narcotics produce withdrawal symptoms that are protracted but less severe. The symptoms associated with heroin/morphine addiction are usually experienced just prior to the next scheduled dose. Initial symptoms may include watery eyes, runny nose, yawning, and sweating, followed by restlessness, irritability, loss of appetite, nausea, and tremors. The advanced stages are marked by severe depression, vomiting, elevated heart rate and blood pressure, muscle spasms, chills, excessive sweating, and pain in the bones, back muscles, and extremities. A suitable narcotic can be administered at any stage of withdrawal that will dramatically reduce the symptoms. Without intervention, the effects of withdrawal will slowly subside and most of the physical symptoms will disappear in 7–10 days. Drug users often abuse a specific or preferred drug, and it is not uncommon to substitute drugs that produce similar effects (often the same drug class). Drugs within a class are often compared using terms, such as potency and efficacy. Potency defines the amount (dosage) of a drug that must be taken in order to produce a desired effect. Efficacy is the capacity of a drug to produce a given (desired) effect, regardless of dose. The physical effects produced by any drug can vary significantly and are largely dependent on the dose, route of administration, and individual sensitivity to the drug. Concurrent use of several types of drugs may either enhance or block specific effects. As a result, abusers often take more than one drug in an effort to increase the desired effects, while minimizing unwanted side effects. This practice can dramatically increase the risks associated with drug abuse because the overall effects cannot be accurately predicted. This suggests that a genetic component may exist that predisposes individuals to either drug toxicity or addictive behavior.
5.3.2
Psychological Dependence
Psychological dependency is a perceived “need” or “desire” for a drug and is commonly associated with addiction. Individuals who are psychologically dependent often feel (or believe) that they cannot function normally without continuous drug use. Psychological dependency can last much longer than physical dependency and is a primary reason for relapse after a period of either treatment or abstinence. The psychological dependence associated with narcotic addiction is complex and protracted. Addicts often ponder drug use long after the physical need for the drug has subsided. They may feel either uneasy or overwhelmed while performing daily activities without the influence of drugs (sober). There is a high probability of relapse after narcotic withdrawal, if changes are not made to either the addict’s physical environment or behavioral motivators (associates). There are two major patterns of narcotic abuse or dependence observed in the United States. One involves individuals whose drug use was initiated within the context of medical treatment. These individuals escalate use by obtaining fraudulent prescriptions or elicit drugs. The other, more common pattern is initiated outside the clinical setting through either the experimental or recreational use of narcotics. The majority of individuals in this category may abuse narcotics periodically for either months or even years. Although they may not become addicts, the social, medical, and legal consequences of their behavior are very serious. Some experimental users will escalate narcotic use to the point of physical and psychological dependency. Individuals initiating drug use at an early age are more likely to progress from casual use to dependence and addiction.
5.5
5.4
Hazards of Drug Abuse
63
Drug Abuse
Narcotics are used therapeutically to treat pain, suppress cough, alleviate diarrhea, and induce anesthesia. They may be administered either orally, by injection, in suppository form, or through the skin (skin patches). Aside from their curative effects, narcotics produce a general sense of well-being by reducing tension, anxiety, and aggression. Although these effects are helpful in a clinical setting, they are also a contributing factor in their abuse. Narcotics are often smoked, sniffed, or injected when abused (Fig. 5.1). A wide range of side effects (varying in severity), such as drowsiness, inability to concentrate, apathy, decreased physical activity, constriction of the pupils, dilation of subcutaneous blood vessels (causes flushing), constipation, nausea, vomiting, and respiratory depression, may accompany excessive and prolonged use of narcotics. The therapeutic and toxic effects become more pronounced with increased dosage. Apart from acute intoxication, there is generally no loss of motor coordination or slurred speech with narcotic use. This is in contrast to the general effects of most depressants.
5.5
Hazards of Drug Abuse
The health hazards of illicit drug use include an increased risk of infection, disease, and overdose (Fig. 5.2). Pharmaceutical products are manufactured in a controlled environment under strict regulatory control. The production process is well documented as is the concentration and purity of the final product. By contrast, street drugs produced in clandestine labs have
Fig. 5.1 Common vehicles used for narcotic abuse: smoking pipe, cigarette containing narcotics, injection needle, water pipe, equipment, and container used to make narcotic cigarettes.
Fig. 5.2 The destructive nature of drug abuse is illustrated in the arms of the two addicts. Infection (left) and scars and track marks from injection (right).
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unknown compositions. Health issues and medical complications common to most narcotic abusers are the result of adulterants, contaminants, and/or nonsterile injection practices. Skin, lung, and brain abscesses, endocarditis (inflammation of the lining of the heart), hepatitis, and AIDS are prevalent among narcotic abusers. The composition and purity of illegally manufactured drugs is always in question. Therefore, the physiological effects are inconsistent and unpredictable and can be fatal in some cases. Physical signs of narcotic overdose include constricted (pinpoint) pupils, cold clammy skin, confusion, convulsions, severe drowsiness, and respiratory distress.
5.6
Structural Relationships
5.6.1
Analogs
The question of analogs is often encountered in trials involving either drugs or drug-related crimes. It is often asked if a specific chemical is an analog of a scheduled controlled substance. A substance is considered an analog of another substance if: 1. Both substances are structurally similar. 2. Both substances have the same chemical reactivity. 3. Both substances have similar physiological effects. 4. Both substances have similar toxicological effects. 5. Both substances have similar addictive natures. The two substances must satisfy at least two of the above conditions to be considered analogs. For example, pseudoephedrine is structurally similar to methamphetamine and is used as a precursor in its production. However, pseudoephedrine does not have the same reactivity or physiological and toxicological effects as methamphetamine. Thus, pseudoephedrine is not an analog of methamphetamine. HO CH
CH3
CH3
CH2
CH
CH
HN
HN
CH3
Pseudoephedrine
CH3
Methamphetamine
Diagram 5.1
Bufotenine and psilocin are analogs; note the similarity in structures.
CH3
HO CH2
CH3
OH CH2
N CH2
CH3
N H Bufotenine (5-hydroxy-N,N-dimethyltryptamine)
N CH2
CH3
N H Psilocin (4-hydroxy-N,N-dimethyltryptamine)
Diagram 5.2
5.6.2
Designer Drugs
The classification of a particular substance as an illegal drug, controlled substance, or designer drug is based on its molecular structure (structural formula). In an effort to circumvent these legal restrictions, underground chemists modify the structure of existing drugs (legal and illegal) to produce analogs known as designer drugs. For example, MDMA (street name: ecstasy) was “designed” from MDA in an effort to evade the laws and regulations controlling MDA.
5.6
Structural Relationships
65 CH3
O N
O
H
H
MDA (3,4-Methylenedioxyamphetamine)
CH3
O N
O
H
CH3
MDMA (3,4-Methylenedioxymethamphetamine)
Diagram 5.3
The most common types of designer-drug analogs are phencyclidine (PCP), fentanyl and meperidine (synthetic analgesics), and the stimulants/hallucinogens amphetamine and methamphetamine. Designer drugs are often much stronger and more toxic than their precursor counterparts, and brain damage is possible with only a single dose. The federal government has passed legislation regulating all chemicals that are structurally similar to controlled drugs. These laws are designed to stop observed patterns of designer-drug production and usage.
5.6.3
Isomers
Isomers are compounds that have the same number and types of atoms (same chemical formula) but differ in the structural arrangement of the atoms. Isomers have different chemical and physical properties. There are several types of isomers, and the differences are indicated in the name of the isomer. Structural: Compounds with the same molecular formula but a different connectivity of atoms (different structures). Positional: Compounds with the same molecular formula but differing in the position/location of an atom or functional group. Stereoisomers: Compounds with the same molecular formula and same connectivity but differing in the arrangement of atoms in the three-dimensional space. Diastereomers: Compounds with the same molecular formula that are not mirror images of each other.
HO
HO NH
NH CH3
CH3 CH3
CH3 Ephedrine
Pseudoephedrine
Diagram 5.4
Enantiomers: Compounds with the same molecular formula that are nonsuperimposable mirror images of one another. They must contain at least one chiral carbon, a carbon bound to four different atoms or groups. The nonsuperimposable mirror images are differentiated by their ability to rotate plane-polarized light and designated as d or l. The d- and l-forms of methamphetamine are an example.
Mirror H N
CH3
CH3 d-Methamphetamine
Diagram 5.5
H 3C
H N
Flip horizontally
CH3 l-Methamphetamine
H N
CH3 CH3 l-Methamphetamine
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5.7
Controlled Substance Statutes
5.7.1
Controlled Substances Act
Forensic Language
The Controlled Substances Act (CSA) regulates five classes of drugs in the United States: narcotics, depressants, stimulants, hallucinogens, and anabolic steroids. Each class has distinguishing properties, and the drugs within each class often produce similar effects. However, all controlled substances, regardless of class, share a number of common features. With the exception of anabolic steroids, most alter mood, thought, and feelings by targeting the central nervous system (brain and spinal cord). Drug abuse occurs when drugs are used in a manner (or amount) inconsistent with either the medical or social patterns of use in a particular culture. In legal terms, the nonsanctioned use of substances controlled in Schedules I through V of the CSA is considered drug abuse. Drugs classified in the CSA can be used legally for medical treatment under the supervision of a licensed physician; however, the use of these same drugs (or intended use) outside the clinical setting is drug abuse.
5.7.2
Controlled Substances Laws
The production, transportation, distribution, prescription, possession, and consumption of all narcotics, depressants, stimulants, hallucinogens, and anabolic steroids are strictly controlled and regulated. The controlled substances laws impose mandatory penalties (fines or imprisonment) on any individual or entity engaged in illegal activity relating to drugs classified in the CSA. The severity of the penalty depends on the quantity and type of controlled substances and may vary from state to state. A few of the drugs regulated by CSA are listed below under the appropriate schedule.
5.7.2.1 Schedule I Drugs with a high potential for abuse and little to no medicinal value fall under schedule I (typically hallucinogens). 1. Cocaine base 2. Codeine base 3. GHB 4. Heroin and other opiates not listed in schedule II 5. LSD 6. Marijuana or its psychoactive ingredient (tetrahydrocannabinol) 7. Methaqualone 8. Mescaline, including peyote plant and its components 9. Morphine derivatives 10. PCP 11. Tryptamines (a) Synthetic analogs: All: (b) Natural: • Bufotenine: Pure form or present in: – Yopo seeds – Toadstool mushrooms – Bufo toads • Psilocin/psilocybin: Pure form or in mushrooms. 5.7.2.2 Schedule II Drugs with an equal potential for abuse and medicinal use fall under schedule II (generally stimulants). 1. Barbiturates (most analogs)Cocaine: all salts 2. Levo-methorphan 3. Methadone 4. Morphine 5. Opium (raw, extracts, derivatives, and any opiates not listed in schedule I) 6. PCC (a precursor to PCP)
5.8
Controlled Substance Submission to Crime Laboratories
67
7. Phenethylamine family: (a) Amphetamine, its salts and isomers (b) Methamphetamine, its salts and isomers (c) N,N-dimethylamphetamine, its salts and isomer (d) Phenyl-2-propanone (P2P) (e) MDA (f) All analogs of phenethylamine
5.7.2.3 Schedule III Drugs with less potential for abuse and more for medicinal use fall under schedule III (most anabolic steroids and depressants, some stimulants and prescription drugs). 1. Gamma-hydroxybutyric acid (GHB) and salts 2. Ketamine 3. Lysergic acid 4. Most anabolic steroids 5.7.2.4 Schedule IV Drugs with a low potential for abuse and a high potential for medicinal use fall under schedule IV (typically depressants not listed in schedule III). Many prescription drugs are included in this category, as are precursors used in the manufacturing of controlled substances. 1. Atropine sulfate 2. Barbital 3. Clonazepam 4. Diazepam 5. Phenteramine 5.7.2.5 Schedule V This schedule contains chemicals and precursors typically used in the manufacturing of controlled substances. There is considerable overlap between this category and regulated substances. 1. Barbituric acid, a precursor to barbiturates 2. Phenylpropanolamine, a precursor to amphetamine 3. Piperidine, a precursor to PCC 4. d-Lysergic acid, a precursor to LSD 5. Ephedrine/pseudoephedrine and its salts, precursors to methamphetamine 6. Safrol, a chemical used in the manufacturing of methamphetamine 7. Gamma hydroxybutyrolactone (GBL), a precursor to GHB 8. Hydroiodic acid, a chemical used in the manufacturing of methamphetamine
5.7.3
Controlled Substance: Charges and Offenses
The charges listed in Table 5.1 are taken from the State of California Health and Safety Codes.
5.8
Controlled Substance Submission to Crime Laboratories
Controlled substances are submitted to forensic laboratories from law-enforcement agencies in the local vicinity. Specially trained law-enforcement personnel follow the case-submission policies of the forensic laboratory. In general, all case evidence is sent to the laboratory in sealed and labeled bags or envelopes. The bags or envelopes will contain all agency-related case information, such as the suspect’s name, agency name and case number, date of crime, and the quantity of suspected substance.
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Table 5.1 Controlled substance: charges and offenses Charge 11350 11351 11351.5 11352 11353 11353.1 11353.5 11353.6 11355 11357 11358 11359 11360 11361 11362 11362.5 11362.9 11363 11364 11364.5 11364.7 11365 11377 11378 11378.5 11379 11379.2 11379.5 11379.6 11379.7 11379.8 11380.5 11383
5.9
Offense Possession of specified controlled substance (schedule I) Possession or purchase for sale of specified controlled substance (schedule I) Possession or purchase for sale of cocaine base Importing, selling, transporting, and or furnishing controlled substance (schedule I) Adult including minor to violate provisions (schedule I) Penalty enhancement for adult soliciting minor (schedule I) Adult providing controlled substance in a specified area (schedule I) Drug trafficking on or within 1,000 ft. of school ground – penalty enhancement (schedule I) Substances provided in lieu of controlled substance Unauthorized possession of marijuana Unauthorized planting of marijuana Unauthorized possession of marijuana for sale Unauthorized selling, transporting, importing, selling, furnishing of marijuana Adult employing minor or selling to minor Felony offense for bigger quantity of marijuana Medical use of marijuana California Marijuana Research Program Planting, cultivating, processing peyote Possession of devices (paraphernalia) for injecting or smoking controlled substance Drug paraphernalia for sale Unlawfully providing drug paraphernalia Presence where controlled substance unlawfully smoked or used Possession of specified controlled substance (schedule II) Possession or purchase for sale of specified controlled substance (schedule II) Possession for sale of PCP Importing, selling, transporting, and/or furnishing controlled substance (schedule II) Possession for sale of ketamine Importing, selling, transporting, furnishing PCP Manufacturing or processing controlled substance Penalty enhancement for manufacturing or processing controlled substance Penalty enhancement for possessing controlled substance Drug violation in public parks and beaches Possession of chemicals, precursors, solvents, and/or glassware for manufacturing of a controlled substance
Drug Cases in Crime Laboratories
The property section of the crime laboratory receives drug-related case information from client agencies via mail, UPS, or personal courier. They are responsible for logging case information into a database that generates a laboratory case number. All evidence is labeled with the designated laboratory case number and stored in a case-examination locker. The case-examination locker is accessible to all analysts in the forensic-chemistry section. Prior to either examination or opening of a case, the analyst compares the computer entries to the information on the evidence package. This extra step minimizes data-entry errors and ensures that the analyst has the correct case evidence. Following the data-entry review, the analysts open a case. The initial activity of the forensic chemist is strictly inventory. All evidence is carefully recovered from its packaging, weighed, and visually inspected. If a case contains more than one item, the analyst examines one item at a time to avoid cross-contamination. The forensic chemist then performs testing on suspected controlled substances. A detailed record of all activities is kept at each stage of the examination. When the examination of the evidence is complete, the analyst reseals the evidence, initials and dates the seal, and places the evidence in the outgoing evidence locker for release to the submitting agency. Forensic laboratories do not store evidence, including controlled substances, after completing their examination.
5.13
Qualifications and Education
69
Table 5.2 Standard usable quantities of controlled substances Substances Amphetamine Cocaine base Codeine Dihydrocodeinone Hashish Heroin LSD MDA/MDMA Methamphetamine Opium PCP Psilocin/psilocybin: THC
Dosage 10 mg 10 mg 60 mg 5 mg 35 mg 5 mg 0.05 mg 100 mg 5 mg 100 mg 5 mg 10 mg 3 mg
Substances Barbiturates Cocaine HCl DET/DMT DMT and other analogs Hash oil Hydromorphine Marijuana Mescaline Morphine Hydrocodone Peyote STP
Dosage 100 mg 10 mg 60 mg 50 mg 21 mg 2 mg 500 mg 500 mg 10 mg 5 mg 10 mg 3 mg
LSD Lysergic acid, MDA 3,4-Methylenedioxyamphetamine, MDMA 3,4-Methylenedioxymethamphetamin (ecstacy), PCP Phenylcyclohexylpiperidine (commonly shortened to phencyclidine), THC Tetrahydrocannabinol, DET N,N-diethyltryptamine, DMT N,N-dimethyltryptamine, STP 2,5-dimethoxy-4-methylamphetamine (STP serenity, tranquility, peace, also called DOM)
5.10
Examination of Controlled Substances
Examination of a controlled substance is a three-stage process. The first stage is a visual inspection of the suspected substance. The analyst relies on experience and the results of the visual inspection to determine the course of the second stage. The second stage consists of a series of color-screening examinations to determine the most suitable confirmatory method to use on the substance. Finally, a confirmatory examination is performed to identify the substance. The analyst reports the collective results from the color-screening- and confirmation examinations and submits a conclusion.
5.11
Usable Quantity
The forensic chemist is not qualified to give testimony on the physiological effect(s) of a given quantity of controlled substance. This is the responsibility of a forensic toxicologist. However, the Federal Drug Enforcement Agency (DEA) has developed a list of controlled substances containing standard dosages. The data listed in Table 5.2 was obtained from this list.
5.12
Court Testimony
An expert witness can testify in a court of law once their area of expertise has been established and recognized by the court. Witnesses are frequently asked questions about their education, qualifications, and relevant experience to determine if they qualify as an expert. The court will render a decision based on the answers and either accept or reject the witness as an expert. If accepted, the witness is qualified to give expert testimony relevant to the case. The list below contains representative questions that could be used to establish expertise.
5.13 1. 2. 3. 4.
Qualifications and Education
What is your educational background? What do you do for a living? How long have you been working in this field? What are your job responsibilities?
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5. 6. 7. 8. 9.
What is your practical training and experience in this field? What factors qualify you as an expert in the field of controlled substances? Are you familiar with procedures used to test this substance? How many times have you tested this substance? Have you previously testified as an expert in any court of law? (a) How many times? (b) In what courts? 10. Why do you consider yourself an expert in the field of forensic chemistry? The following court-related questions are provided for informational purposes only. They are intended to provide you with a glimpse of an actual trial setting.
5.14 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15.
Questions
Describe the differences between natural drugs and synthetic drugs. Discuss the difference between an analog and a precursor. Could a precursor be an analog of a controlled substance? Define an isomer and list three types. List four physical effects of drugs use. Define physiological effects of drugs use. What is the difference between psychological dependence and physical dependence? What differentiates synthetic drugs from natural drugs? What is the difference between a synthetic drug and a designer drug? List two routes of administration of drugs. Describe the difference between potency and physical dependence. Describe the three stages of substance identification. Name three schedule III drugs. What is the usable quantity of morphine? List three characteristics of analogs.
Suggested Reading Abadinsky, H. Drug Use and Abuse: A Comprehensive Introduction, 6th ed.; Brooks/Cole: New York, 2008; chaps. 1 & 7. California Law: California Health and Safety Code. http://www.leginfo.ca.gov/.html/hsc_table_of_contents.html (accessed April 2009). Doweiko, H.E. Concepts of Chemical Dependency, 7th ed.; Brooks/Cole Publishing: New York, 2009; chap. 4. Faupel, C.; Horowitz, A.; Weaver, G. The Sociology of American Drug Use, 2nd ed.; Oxford Press: New York, 2009; chaps. 1 & 3. U.S. Drug Enforcement Agency. http://www.usdoj.gov/dea/pubs/csa.html (accessed April 2009).
6
Forensic Documentation
6.1
Introduction
Documentation is the foundation of science as well as the hallmark of a sound legal system. It is often said, “If it is not written down it does not exist.” It is absolutely essential to properly document each step of any examination process. Investigators and forensic personnel are required to submit evidence that appropriate tests were performed and that the results presented in court are (in fact) the test results observed either in the laboratory or at the crime scene. Memory is no longer considered either reliable or trustworthy, and proof through documentation has become the standard for acceptance. Scientific results must be reproducible before they are recognized by the scientific community. Documentation provides a mechanism for peer review, replication, and research advancement. Examination procedures performed on physical evidence must be properly recorded, along with results. The results must support and justify the conclusions presented in the final report. More importantly, an expert in the same field should agree with the report’s conclusion. The reviewer may have a different opinion, but he must agree that the records support the conclusion. Documentation procedures used in forensic laboratories generally have three common components, each with its own requirements. They are chain of custody, case notes, and the case report.
6.2
Chain of Custody
The chain of custody is a document (or series of documents) that tracks the location of evidence from collection (crime scene) to final disposition (court). The chain of custody maintains the integrity of evidence through accountability. It requires the examiner to document when, and from whom, the evidence was initially received and when, and to whom, the evidence was transferred. It is generally accepted that the evidence is in the examiner’s sole care and custody during this period. The documentation procedure usually requires an official form with supplemental notations in the examiner’s working notes. The details of examination procedures are rarely addressed in the chain of custody. Typically, they include the date and time of an examination, the identity of the person performing the examination, and the date and time the evidence was transferred, returned, or released. The law does not stipulate categories of transfers. Therefore, the transfer of evidence within a laboratory is documented in the same manner as a transfer of evidence between laboratories. The early use of mass spectrometry illustrates the importance of chain-of-custody documentation. The mass spectrometer is a highly specialized analytical instrument. The analyst had to rely on the operator to perform this specific examination and often had no direct knowledge of how the evidence was handled once it was transferred. Although a forensic chemist could interpret the resulting data and knew the theoretical basis of the instrument’s operation, they could not provide direct knowledge that every procedure was followed. As a result, chain-of-custody documentation was required.
J.I. Khan et al., Basic Principles of Forensic Chemistry, DOI 10.1007/978-1-59745-437-7_6, © Springer Science+Business Media, LLC 2012
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6.3 6.3.1
6
Forensic Documentation
Case Notes Types
Methods of documenting case-related information are contained in the laboratories’ standard-operating-procedures manual. However, these manuals often provide only a list of requirements and rarely address the details of recording information. Case notes may be either very simple or highly detailed, depending on the individual practice of the analyst. Regardless, they must be accurate and comprehensive. Incomplete case notes reflect negatively on the analyst and can cause complications at trial. There is a notable difference between incomplete notes and messy notes; incomplete notes lack accuracy, while messy notes are simply difficult to read. When documenting evidence, remember the old saying, “A picture is worth a thousand words.” It is a good practice to take pictures of unusual evidence (Fig. 6.1). If an item contains a large number of specimens, each piece must be individually documented (Fig. 6.2). It is often helpful to use abbreviations in case notes for simplicity and clarity, but do not overuse them (Fig. 6.3). Be sure abbreviations, if used, are from an approved list, and never use those that are self-created or ambiguous. If an error is discovered in your notes, simply cross out and initial the error, and date and initial the correction (Fig. 6.4). Never obliterate errors or use whiteout; this may cause suspicion (Fig. 6.5).
Fig. 6.1 Pictures always assist in understanding a crime scene. (a) A single picture is often better than pages of descriptive notes. (b) Samples of cocaine pricks. (c) An imprint on a cocaine brick.
6.3 Case Notes Fig. 6.2 Note how useful it is when each item is described separately. This minimizes possible ambiguity.
Fig. 6.3 Examples of notes with abbreviations.
Fig. 6.4 Properly made corrections are initialed and dated to maintain the integrity of the documentation process.
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Forensic Documentation
Fig. 6.5 Example of unacceptable corrections: material is obliterated, undated, and not initialed.
6.3.2
Purpose
The case notes are the second component in the documentation process. They consist of handwritten notes, worksheets, examination results, analytical data, and administrative paperwork. The case notes serve two functions; first, they document all aspects of the examination process, and second, they are used as references by the examiner for report writing and preparation of testimony. Case notes are a complete record of all case activity in the criminal-justice system. Although the final report will provide a summary and conclusion of the entire process, the history of the case is contained within the pages of the case notes. In recognition of the fact that examinations produce more information than that contained in laboratory reports, regulatory and accreditation agencies require that case notes be maintained. Also, peer review requires the availability of information (case notes) used to formulate scientific opinions.
6.3.3
Content
The American Society of Crime Laboratory Directors (ASCLD) criteria states that a case file must be generated for each case and that each file must be uniquely identified. The International Organization for Standardization (ISO-17025:2005) criteria are slightly more specific; it details the type of information that must be included in technical records. Surprisingly, accreditation agencies, such as ASCLD and the ISO, do not regulate the contents of the case files. The following list contains items commonly found in a case file. • Copy of all final reports • Copy of all evidence-submission forms • Copy of all relevant chain-of-custody documents • Itemized description of the type and condition of the packaging when received (sealed vs. unsealed) • Itemized description of evidence received • Detailed description of the items examined • Description of the examination(s) performed • Handwritten notes on examinations performed with observations and evaluations, to include but not limited to: – Original sample weight – Results of wet chemical tests – Results of instrumental examinations – Sample-preparation techniques • All original charts, graphs, photographs, photomicrographs worksheets, analytical data or any other type of laboratory generated information – Photocopies are an acceptable replacement for original information that is not in a form conducive to storage in the case file • Copies of written reports related to submitted evidence • Correspondence or telephone notes related to the case Each page of the case file is required to have additional information as a quality-assurance measure. These items are: • The agency’s unique case number • The forensic chemist’s handwritten signature or initials • The date each page was generated • The page number and total number of pages – Machine-generated dates, record numbers, and pagination are acceptable.
6.4
Case Report
6.3.4
75
Format
Accreditation agencies do not regulate the format of case files. Laboratory-approved forms, official police reports, and instrumental data sheets are usually provided. The format of handwritten notes (case notes) may, or may not, be specified in the laboratories standard-operating-procedures manual. Handwritten notes have two common formats; one is simply a series of notations on a blank sheet of paper, and the other consists of preprinted worksheets designed to streamline the documentation of repetitive testing procedures. Regardless of format, each page of notes should contain the examiner’s initials, the date of the examination, the case number, exhibit number, page number, and the total number of pages (including pages of instrumental data). Legibility is a key component of handwritten notes. If shorthand is used, it must be defined and clarified in order for the peer-review process to be effective. Ambiguity may lead to misinterpretation.
6.3.5
Dissemination
Whether or not case notes are admissible as evidence or are subject to discovery is an ongoing debate. Some laboratories feel that case notes are the protected, personal property of the forensic chemist. They will go to great lengths to prevent their discovery, citing the case notes are summarized in the final report. Others will openly release case notes upon request as a supplement to the final report. The case-note dissemination policy is ultimately regulated by local statutes, case law, and individual laboratory policy.
6.4 6.4.1
Case Report Purpose
The case report is the final component in the documentation process. This report contains a summary of examination procedures, the case notes, analytical data, and the professional opinion of the examiner. This report should be a stand-alone document requiring little, if any, clarification from the examiner.
6.4.2
Format and Content
Generally, case-report formats are determined by individual laboratories; however, most formats are based on the criteria set forth by the American Society of Testing Materials (ASTM), the ISO 17025, or ASCLD. Regardless of format, each case report includes: • Name of the laboratory performing the examination • Case file number • Name of the individual requesting the examination(s); • Examiner’s name • A list and description of the evidence submitted for examination • Description of the examination(s) performed • Results of the examination • Chain of custody of documentation As previously stated, the case report should be a stand-alone document. While this is true for some sections of the report, it does not necessarily apply to the entire document. For example, courts often require additional testimony to clarify the examination description and result sections, while the administrative segment may be accepted as written in the report. Some formats separate all the sections, while others do not; for example, a description of the testing process could be included in the results narrative. In either case, the reader should be able to confirm the identity of the controlled substance along with the testing procedures used to make that determination.
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6.5
Forensic Documentation
Examples
Below are two examples of different formats used to report examination results.
6.5.1
Example One
Items 1. White powder 2. Plant material Exam Drugs Results 1. Contained cocaine, a narcotic drug. Substance mass 1.32 g. A usable quantity. 2. Contained marijuana. Substance mass 6.29 g. A usable quantity.
6.5.2
Example Two
Items 1. Item 1: A paper packet containing a white powder. 2. Item 2: A plastic bag containing a green leafy plant material. Results 1. Examination of Item 1 using wet chemical tests, microcrystal tests, gas chromatography, and infrared spectroscopy concludes that Item 1 contained a usable quantity of cocaine. The total substance mass was 1.32 g, which is considered a usable quantity. Cocaine is defined as a narcotic drug under ARS 13-3401.20. 2. Examination of Item 2 using microscopic and wet chemical techniques concludes that Item 2 contained marijuana. The total substance mass was 6.29 g, which is considered a usable quantity. Marijuana is defined as a narcotic drug under ARS 13-3401.20. Example One provides the information in a basic format. The reader can quickly identify each exhibit, the quantity of substance, its classification under governing statutes, and a case-law opinion on the amount of substance seized. However, information justifying the examiner’s conclusions is not included. This omission may lead to an unnecessary and time-consuming court appearance. Example Two represents a more complete report. It not only contains the same information as example One but also includes a description of the tests used to justify the examiner’s conclusions. This addition may not require a court appearance by the examiner.
6.6 1. 2. 3. 4. 5. 6. 7.
Questions Describe the process of chain of custody. What are the advantages of chain of custody? Please explain to the jury the procedure of evidence receipt. Name two organizations that regulate case-documentation procedures. List seven items often included in a case report. What information is commonly included in case notes? What do you do with the case notes after completion of the analysis?
Suggested Reading
8. 9. 10. 11. 12.
Describe the difference between incomplete notes and messy notes. Is it possible to alter case notes? Explain. Describe the process of correcting errors found in case notes. What activity initiates evidence analysis? What did you do with the evidence after the analysis is complete?
Suggested Reading The American Society of Crime Laboratory Directors. http://www.ascld.org/ (accessed May 2009). International Organization for Standardization (ISO). http://www.iso.org/iso/home.htm (accessed May 2009).
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Chemical Screening
7.1
Introduction
Chemical-screening methods are presumptive tests commonly used to initiate the process of substance identification. These simple reactions cannot identify the substance without uncertainty; however, they do provide preliminary confirmation of the presence of either a particular functional group or a generic molecular structure. Chemical-screening tests produce a distinct color when the reagents are mixed with compounds containing a specific functional group. Although not highly specific, these preliminary tests will determine which subsequent method is best suited to identify the substance. Unfortunately, it is not uncommon for two people to describe the same color in different terms. The interpretation and reporting of colors can be influenced by the concentration of the sample, the presence of diluents and adulterants, the age of the reagent, and test reaction times. Also, color transitions and instabilities may result in the formation of multicolored complexes. The subjective and inconsistent nature of color formation and reporting may call into question the use of color screening as a viable method, especially in the area of controlled-substance examinations. This fact should be recognized and allowances made, and the forensic chemist must be prepared to justify reported conclusions.
7.2
Chemistry of Color Formation
Visible light (white light) contains a mixture of wavelengths in the electromagnetic spectrum, ranging from approximately 350 nm (violet) to 750 nm (red). If some of these wavelengths are removed from white light, it is no longer observed as white. All matter is composed of atoms and/or molecules. If an object is colored, the atoms or molecules absorb a portion of white light, thus removing it from the visible range. The observed color of the object is not the light that is absorbed; it is the remaining wavelengths that are reflected (not absorbed). For example, if red light (~750 nm) is absorbed by an object, it is removed from white light and the object appears green (a mixture of the reflected wavelengths). The ability (or capacity) of a substance to absorb (or not absorb) light depends on its chemical properties, i.e.; molecular structure, bond energies, electron arrangement, etc. A change in chemical properties can result in a change in color. A chemical reaction is any process that results in a chemical change. Therefore, a chemical reaction will produce different colored products if it changes the light-absorbing capacities of the reagents (starting material). Color-screening tests produce distinct colors by changing the light-absorption properties of controlled substances. These changes are often directly related to a small change in either the orientation or the location of electrons in the structure. For example, primary amines will react differently than secondary amines when mixed with specific reagents. Tertiary amines may or may not react with reagents that produce a change in primary and/or secondary amines. The location of electrons in the three-dimensional structure of a molecule is one of the factors that determine color. Colorscreening reagents utilize four general mechanisms to produce a characteristic color change; all are based on changing either the location or the orientation of electrons. A characteristic color is produced when:
J.I. Khan et al., Basic Principles of Forensic Chemistry, DOI 10.1007/978-1-59745-437-7_7, © Springer Science+Business Media, LLC 2012
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1. A screening reagent(s) removes an electron directly from the test compound.
Diagram 7.1
2. A screening reagent(s) adds an unpaired electron directly to the test compound.
Diagram 7.2
3. A screening reagent(s) complexes directly with the test compound, resulting in the addition of an unpaired electron.
Diagram 7.3
7.4
Chemical Color-Test Methods
81
4. A screening reagent(s) bridges two or more test compounds.
Diagram 7.4
The color and intensity (shade) of the products produced in chemical-screening tests may be affected by the acidity of the test solution. The Duquenois–Levine test, the recognized standard in the identification of cannabis resin, relies heavily on the pH of the solution to produce a color change. Addition of the Duquenois reagent to a sample of suspected cannabis resin produces a color change only after the pH is adjusted with hydrochloric acid. The Chen’s test is an example of how intensity is affected by pH. In the Chen’s test (like the Duquenois–Levine test), the color is not observed until the pH of the test solution is adjusted. However, the intensity (shade) of the color is dependent on how the pH is adjusted. The use of a weak base (bicarbonate solution) to adjust pH will produce a shade that is noticeably different from the shade produced using a strong base (hydroxide solution). The addition sequence of reagents in multistep color tests is very important because an error may produce a different result (color). For example, the use of the Marquis’ reagent with 3,4-methylenedioxyamphetamine (MDA) or 3,4-methylenedioxymethamphetamine (MDMA) should produce a green-to-black color transition. However, switching the sequence will produce a purple-to-black transition.
7.3
Limitations of Chemical Color Tests
Color-screening tests are nonspecific. They are only used to confirm the presence of either a functional group or a characteristic structure. They cannot be used to positively identify any substance; however, they can indicate the presence of a specific class of compound. Unfortunately, not all compounds respond to chemical color tests and, in some instances, the screening tests are significantly more complicated than the confirmatory methods. For example, some tryptamines have no known chemical color test and the color test for GHB (g-hydroxybutyrate) is more complicated than the confirmatory examination. These limitations should not preclude the use of chemical color tests. They are an excellent method to effectively differentiate specific classes of compounds.
7.4
Chemical Color-Test Methods
Chemical color tests are generally performed by transferring a small amount of the substance under investigation to either the well of a spot plate or a test tube (Fig. 7.1). Next, the test reagent is added to the substance. Some tests may be conducted in a sequential manner using multiple reagents. In these cases, the results of each step in the sequence are observed and noted. Positive and negative controls should be run on a regular basis to ensure the reliability of the testing reagents. The following is a basic procedure for performing a chemical color test: • Place a small amount of a test sample in either a well of a clean spot plate or an unused culture tube. • Add a few drops of the chemical color reagent and record the immediate color change. – Continue if the test requires more than one reagent. • Add a few drops of the subsequent reagent(s) and record the immediate color change. – Continue adding test reagents as required.
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Fig. 7.1 A spot plate typically used in color-screening tests.
7.5
Documentation
Comprehensive documentation of chemical color tests would include (at minimum): a complete description of reagents (expiration dates, color, physical properties, photographs, etc.), a complete description of test substance (color, physical properties, irregularities, notable markings, identifying characteristics, photographs, etc.), observations during test performance (testing conditions, testing equipment, glassware, spot plate, transition colors from initial mixing to end of test, photographs, etc.), complete description of results (final color, positive or negative, comparison to published results, deviations, supporting evidence for observed results, photographs, etc.). Simply recording a positive (+) or negative (−) result should be avoided because it does not provide adequate information for subsequent peer or technical review. Note: Photographing a chemical color test may or may not provide adequate documentation. A photograph cannot illustrate short-lived color transitions that may have been observed during the examination; however, they can accurately prove selected results.
7.6
Chemical Color Tests
We have selected some of the most common and most reliable color-screening tests for discussion. It should be noted that this list is not intended to represent a comprehensive collection of color-screening tests.
7.6.1
Chen’s Test
Reagent 1: • 1% (m/v) copper(II) sulfate (CuSO4) in water Reagent 2: • 8 g sodium hydroxide in 100-ml water (2 M NaOH) Place either 1–2 mg or 1–2 drops of sample in a spot plate, add two drops of reagent 1, then two drops of reagent 2 and note the color. Results: • Produces purple color with ephedrine/pseudoephedrine, phenylpropanolamine, and lidocaine. Note: This test requires a blank because the reagents are light blue. The formation of a copper complex produces the color. Copper(II) acts as a chelating agent connecting two of the target molecules. Ephedrine is shown as an example.
7.6
Chemical Color Tests
83
Diagram 7.5
7.6.2
Dille–Koppanyi’s Test
Reagent 1: • 0.1 g cobalt(II) acetate or, 0.1 g cobalt(II) acetate tetrahydrate • 0.2 ml glacial acetic acid • 100 ml methanol (absolute) Reagent 2: • 5 ml isopropylamine • 95 ml methanol (absolute) Place either 1–2 mg or 1–2 drops of sample in a spot plate, add three drops of reagent 1, then three drops of reagent 2 and note the color. Results: • Purple: glutethimide, theophylline, chlorzoxazone, all barbiturates (except thiobarbs) • Blue/purple: dilantin The colored complex contains cobalt(II) and two target molecules stabilized by two molecules of isopropylamine. Barbiturates are shown as an example.
Diagram 7.6
7.6.3
Mecke’s Test
Reagent: • 1% selenous acid (H2SeO3) in concentrated sulfuric acid Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of the reagent and note the color. Results: • Purple: codeine, diazepam, methcathinone, flunitrazepam, phenylacetone, and oxycodone • Green: opiate alkaloids, i.e., morphine and heroin The reagent oxidizes opiates to a green-colored ortho-quinone of apomorphine. Heroin is shown as an example.
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Diagram 7.7
7.6.4
Marquis’ Test
Reagent 1: • Concentrated sulfuric acid Reagent 2: • Eight to ten drops of 37% formaldehyde in 10 ml of glacial acetic acid Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of reagent 1, then one drop of reagent 2 and note the color. Results: • Orange-to-brown: N,N-dimethylamphetamine, amphetamine, methamphetamine, mescaline, and the pethidine group • Purple: opiate alkaloids, morphine, heroin, and codeine • Brown-red-purple: opium • Pink-to-violet: methadone • Green-to-black: MDA and MDMA (when reagent 2 is added first) • Purple-to-black: MDA and MDMA (when reagent 1 is added first) Color formation from opiate alkaloids is most likely from a complex containing two molecules of the opiate and two molecules of formaldehyde. Its formation is promoted by the presence of a strong acid (e.g., sulfuric acid). The colored complex of heroin is shown.
Diagram 7.8
A bimolecular orange-to-brown-colored carbenium ion complex is formed between two amphetamine or methamphetamine molecules in the presence of the Marquis’ reagent. Amphetamine is shown as an example.
Diagram 7.9
7.6
Chemical Color Tests
85
A bimolecular-molecular green-to-black-colored complex containing two carbenium ions is formed when either MDMA or MDA reacts with formaldehyde in the presence of sulfuric acid. This will occur when reagent 2 is added first.
Diagram 7.10
A bimolecular-molecular purple-to-black-colored complex containing two carbenium ions is formed when either MDMA or MDA reacts with sulfuric acid in the presence of formaldehyde. This will occur when reagent 1 is added first.
Diagram 7.11
7.6.5
Nitric Acid Test
Reagent: • Concentrated nitric acid Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of the reagent and note the color. Results: • Orange-to-red: morphine • Orange: codeine • Yellow: heroin The aromatic portion of heroin, codeine, and morphine (benzene ring) is nitrated at the ortho position. The highly polar nitro group (NO2) generates the colored complex through intramolecular ring closure via hydrogen bonding. Heroin is shown as an example.
Diagram 7.12
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7.6.6
7
Chemical Screening
Primary Amine Test
Reagent 1: • 1 g sodium nitroprusside (nitroferricyanide) • 10 ml acetone • 90 ml water Reagent 2: • 2% sodium carbonate in water Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of reagent 1, then one drop of reagent 2 and note the color. Results: • Blue is positive for the presence of primary amines.
7.6.7
Secondary Amine Test
Reagent 1: • 1 g sodium nitroprusside (nitroferricyanide) • 10 ml acetaldehyde • 90 ml of water Reagent 2: • 2% sodium carbonate in water Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of reagent 1 then one drop of reagent 2 and note the color. Results: • Blue color is positive with some secondary amines, such as MDMA and methamphetamine. This test cannot be used to screen the secondary amines pseudoephedrine, ephedrine, and ketamine.
7.6.8
Tertiary Amine Test
Neutral reagent: • 2% cobalt(II) thiocyanate in water solution Acidified reagent: • 2% cobalt(II) thiocyanate in water solution • Add a few drops of concentrated HCl. Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of the reagent and note color. Results on neutral test: • Blue: cocaine HCl, ketamine, pethidine, methadone, methylphenidate, and methaqualone Results on acidified test: • Blue: cocaine base, phencyclidine (PCP), pethidine, methadone, methylphenidate, and methaqualone
7.6.9
Van-Urk’s Test
Reagent: • 1 g para-dimethylaminobenzaldehyde (p-DMBA) • 10 ml concentrated HCl • 90 ml ethanol • Preparation: Dissolve p-DMBA in ethanol, then add HCl. Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of the reagent and note the color.
7.6
Chemical Color Tests
87
Results: • Purple: LSD (lysergic acid diethylamide) • Blue: indoles, pyrroles, and tryptophan • Yellow: procaine and benzocaine The purple-colored trimolecular complex formed with LSD involves two molecules of LSD and one modified reagent molecule.
7.6.10 Duquenois–Levine Test Reagent 1: • Petroleum ether Reagent 2: • 97.5 ml of 2% vanillin solution in methanol (absolute) • 2.5 ml of acetaldehyde Reagent 3: • Concentrated hydrochloric acid Reagent 4: • Chloroform Procedure: • Wash plant material with petroleum ether. • Place the petroleum-ether extract in a spot-plate well and allow the ether to evaporate. • Add a few drops of reagent 2. • Add a few drops of reagent 3 and note the color. • Add a few drops of reagent 4 and note the color in the chloroform layer. Results: • A positive test for cannabis resin requires two observations: (1) a purple color must form after the addition of reagent 3, and (2) the color must transfer into the chloroform layer after the addition of reagent 4.
7.6.11 Froehde’s Test Reagent: • 0.5% sodium molybdate (Na2MoO4) solution in concentrated sulfuric acid Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of the reagent and note the color. Results: • Purple: opiate alkaloids
7.6.12 Janovsky Test Reagent 1: • 0.2% (m/v) meta-dinitrobenzene in 2-propanol Reagent 2: • 10% (m/v) potassium hydroxide in methanol (absolute) Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of reagent 1, then one drop of reagent 2 and note the color. Results: • Purple: diazepam, methcathinone, flunitrazepam, phenylacetone, oxycodone
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7.6.13 Weber Test Reagent 1: • Freshly prepared 0.1% (m/v) Fast Blue B or Diazo Blue B (O-dianisidine, tetrazotized) solution in water Reagent 2: • Concentrated hydrochloric acid Place either 1–2 mg or 1–2 drops of sample in a spot plate, add one drop of reagent 1, then one drop of reagent 2 and note the color. Results: • Red color after the addition of reagent 1, followed by a blue-green color after the addition of reagent 2 indicates the presence of psilocin or psilocybin.
7.7
Summary of Chemical Color Tests
The flowchart below is a summary of the color-screening methods discussed in this chapter (Fig. 7.2). The chart illustrates the progressive nature of chemical screening and the correlation that exists among and between different tests. Although the chart could be used to isolate atypical controlled substances (using different combinations), the results shown are representative of those most frequently encountered. Remember, color-screening methods are presumptive tests and should never be used as definitive proof in the identification of a substance.
7.7
Summary of Chemical Color Tests
Fig. 7.2 Results of color-screening tests on frequently encountered controlled substances.
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7.8 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.
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Chemical Screening
Questions Describe the use of color-screening methods in forensic chemistry. Describe the chemistry of color formation. List three ways colors are produced through chemical reactions. List two limitations of chemical color tests. Outline the documentation process for color tests. Please explain to members of the jury why the Marquis’ test used in this case to test MDA produced two different results. Why is it necessary to run a blank control when using Chen’s test? Please explain to members of the jury what test you used to determine the sample was cannabis resin. Explain the procedure and results. Describe two tests used to screen for heroin. What test is commonly used to screen for LSD? Why are blank controls always used in chemical color tests? Identify the substance indicated from the following results: Marquis’ test, no color; tertiary amine test (neutral), no color; tertiary amine test (acidified), blue. Identify the substance indicated from the following results: Marquis’ test, orange-to-brown; secondary amine test, blue. Identify the substance indicated from the following results: Marquis’ test, no color; tertiary amine test (neutral), no color; tertiary amine test (acidified), no color; Chen’s test, no color; Janovsky’s test, no color; Dille–Koppanyi’s test, no color; Van Urk’s test, purple.
Suggested Reading Christian, D. R. Jr. Analysis of Controlled Substances. In Forensic Science: An Introduction to Scientific and Investigative Techniques, 3rd ed.; James, S. H.; Nordby, J. J., Eds.; CRC Press: Boca Raton, FL, 2009. Cole, M. D. The Analysis of Controlled Substances; John Wiley & Sons: New York, 2003; Appendix 1. Presumptive Color Tests. Jeffery, W. Chapter 19. In Clarke’s Analysis of Drugs and Poisons 2004; Moffat, A. C.; Osselton, M. D.; Widdop, B., Eds.; Pharmaceutical Press: London, 2004. Jones, H. S.; Wist, A. A.; Najam, A. R. Spot Tests: A Color Chart Reference for Forensic Chemists. J. Forensic Sci. 1979, 24, 631–649. Jones, L.; Atkins, P. Chemisty: Molecules, Matter, and Change, 4th ed.; W.H. Freeman and Company: New York, 2000; p 267 & chapter 21. King, L.; McDermott, S. Chapter 2. In Clarke’s Analysis of Drugs and Poisons 2004; Moffat, A. C.; Osselton, M. D.; Widdop, B., Eds.; Pharmaceutical Press: London, 2004. United Nations. Methods for Testing Barbiturate Derivatives Under International Control. A Manual for Use By National Narcotics Laboratories; ST/NAR/18; United Nations: New York, 1989. United Nations. Rapid Testing Methods of Drugs of Abuse. A Manual For Use by National Law Enforcement and Narcotics Laboratory Personnel; ST/NAR/13/REV.1; United Nations Publication: New York, 1994. United Nations. Recommended Methods for The Identification and Analysis of Amphetamine, Methamphetamine and Their Ring-Substituted Analogs in Seized Materials. Manual for Use by National Drug Testing Laboratories; ST/NAR/34; United Nations Publication: New York, 2006.
8
Microcrystal Techniques
8.1
Introduction
Microcrystal test techniques are based on highly developed chemical-precipitation reactions in which a polarized microscope is used to observe and distinguish the different types of crystals formed. Most of these tests were developed in the late nineteenth century for the identification of alkaloids. Over the years, they have been modified and are currently used in the identification of a majority of controlled substances. Despite the fact that they were developed more than 100 years ago, microcrystal tests still have a role in modern forensic chemistry. Microcrystal tests are confirmatory techniques often used to verify the results of preliminary screening methods. They are fast, easy to perform, and can be highly specific. However, there is considerable debate on whether they are specific enough to be used as a confirmatory test. The forensic community is divided on this issue into three main groups. Traditionalists use microcrystal techniques as a confirmatory test in the forensic examination of controlled substances. This older generation of chemists has used wet chemical techniques to identify compounds since the 1960s and 1970s. Although not fully understood at the time, the chemistry of color formation is different from the chemistry of crystal formation. Traditionalists view microcrystal tests as independent tests and perform them in conjunction with color-screening methods. Positive results obtained from two independent tests would represent definitive proof that the sample under investigation is a controlled substance. The modern, younger generations of forensic chemists use microcrystal tests as a preliminary screening tool. They believe the true chemistry behind microcrystal tests is unknown and that analytical examination (i.e., gas chromatography mass spectrometry (GCMS) or Fourier transform infrared (FTIR) spectroscopy) is required before a positive identification can be made. The clinical group does not use microcrystal tests and prefers more sophisticated instrumental analysis. This decision appears to be based more on economic, rather than scientific, reasons. This group believes the automation of GCMS and the chemical reliability of FTIR represent a more efficient and economical method of examination. They consider microcrystal tests to be laborious techniques that require extensive training and skill. To address caseload requirements, the clinical group prefers a single trained technician (to operate either the GCMS or FTIR instruments) over a group of scientists performing wet techniques.
8.2
Advantages of Microcrystal Techniques
Microcrystal tests are a low-cost alternative to GCMS and FTIR that are recognized by the scientific community. The Scientific Working Group for the Analysis of Seized Drugs (SWGDRUG) has established criteria for their use in the identification of controlled substances. Additionally, the American Society of Testing and Materials (ASTM) have established methods for identifying cocaine and methamphetamine using microcrystal tests. In general, microcrystal tests are safe and environmentally friendly. In most cases, the entire analysis can be performed with as little as a single drop of reagent. This is in contrast to the volumes of chemicals required to prepare samples for
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instrumental analysis. For example, a mere 2 ml of organic solvent used in sample preparation for automated FTIR analysis is roughly 40 times the volume required for a typical microcrystal test. Purification of the controlled substance is not required for microcrystal testing. Diluents and impurities generally do not interfere with the crystal features used in the identification process. Characteristic crystals can be observed at sample concentrations approaching 2% (by mass). This sensitivity can detect microgram quantities of controlled substance in a particular sample. A clear advantage of microcrystal tests is their use in the detection of optical isomers (see Chap. 4; Chirality). The identification of enantiomers (optical isomers) is complicated by the fact that, except for optical rotation, they have the same chemical and physical properties. Microcrystal tests can quickly and accurately differentiate optical isomers by forming different crystal structures with each enantiomer. This can play an important role in the analysis of controlled substances when one isomer is controlled and the other is not, or when one isomer can establish a particular method of drug production. It should be noted that microcrystal formation does not affect the chemical and physical properties of the substance; thus, it can be recovered for subsequent testing (i.e., instrumental analysis). This is clearly an advantage if sample quantity is limited.
8.3
Disadvantages of Microcrystal Techniques
The principal disadvantage of microcrystal testing is that it is not applicable to all substances. Crystal-testing procedures do not exist for a number of commonly encountered controlled substances and, given the current debate over their use, this is not likely to change in the near future. Microcrystal testing can produce more than one type of arrangement. The presence of additional crystal-forming agents may interfere with the precipitation of the target compound. This interference may cause either distortions or variations in the expected crystal form (polymorphism). This may complicate the identification process. In such cases, a purification procedure, such as thin-layer chromatography or extraction, is recommended before microcrystal analysis. The formation of a solid crystal in solution begins when individual molecules or ions cluster together. This process of nucleation continues until a visible particle appears. The speed of the nucleation process can influence the shape of the crystal. Crystals with definitive features are formed very slowly; while those formed rapidly can “mechanically trap” undesired particles (i.e., solvent, impurities, dilutants, etc.). The trapped particles can distort the overall structure of the crystal and complicate identification. Highly concentrated samples and reagents will develop crystals rapidly, resulting in polymorphism. Therefore, reagents and samples may require dilution to produce standard crystal forms for comparison and identification. Also, reference samples should be run with all reagents to verify reagent activity. Microcrystal testing is a manual technique. The individual handling of samples and reagents requires care and consistency. The analyst’s results must be reproducible for definitive identification. This aspect is a barrier to automation and may preclude its use in forensic laboratories with a high-volume caseload. Microcrystal techniques lack the versatility of chromatographic methods offering single-step identification, quantization, and documentation. Consequently, many would argue that they are not well suited for the production-oriented clinical environment of the modern forensic laboratory. Identifying compounds using standard crystal features is not inherently subjective. Nonetheless, a degree of subjectivity is always present in the interpretation of crystal test results. Characterizing shapes and structural features is influenced by the experience and training of the analyst, concentration of sample and reagents, presence of interfering compounds, reagent age, and crystal polymorphism. The effective use of microcrystal tests requires training and experience. The analyst must develop recognition of unpredictable reagent behavior through practice. Unfortunately, this requires countless hours behind a microscope.
8.4
Documentation
The results of microcrystal testing should be documented completely. Table 8.1 provides a list of terms and diagrams commonly used to describe crystals. In addition, comprehensive documentation would include: a complete description of reagents (expiration dates, color, physical properties, photographs, etc.), a complete description of test substance (color, physical properties, irregularities, notable markings, identifying characteristics, photographs, etc.), observations during test performance (testing conditions, testing equipment, glassware, spot plate, colors, photographs, etc.), complete description
8.4
Documentation
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Table 8.1 Microcrystal descriptions Crystal Blade
Shape
Description Broad needle
Bunch/Bundle
Cluster with the majority of the crystals lying in one direction
Burr/Hedgehog
Rosette, which is so dense that only the tops of the needles show
Cluster
Loose complex of crystals
Cross
Single cruciform crystal
Dendrites
Multibrachiate branching crystals
Grains Needles
Small lenticular crystals Long thin crystals with pointed ends
Plates
Crystals with the length and width that are of the same magnitude
Prisms
Thick tablet
Rod
Long thin crystals with square cut ends
Rosette
Collection of crystals radiating from a single point
Sheaf
Double tuff
Splinters Star
Small irregular rods and needles Rosette with 4 or 6 components
Tablet
Plates with appreciable thickness
Tuff/Fan
Sector of a rosette
of results (crystal features, sketch, comparison to standard features, deviations, supporting evidence for conclusion, photographs, etc.). Supporting documentation may or may not be required when microcrystal tests are used as a screening method. The documentation requirements are flexible on presumptive tests because the final opinion does not necessarily rely on the results. Regardless, a physical description and diagram of the crystals must be documented for peer review. Microcrystal tests used as a confirmatory method require documentation. It is recommended that a photomicrograph (photograph) be taken of the crystals used for identification. Microcrystal results can easily be challenged as evidence, if the examiner fails to provide documentation of performance and results.
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8.5
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Microcrystal Techniques
Microcrystal Test Techniques
In microcrystal tests, the test sample is dissolved in a solution. A test reagent either is added to the solution or is already present in the solvent. A reaction between the compound of interest and the test reagent forms a solid compound that is not soluble in the test drop. The solid forms uniquely shaped crystals that can be observed with a microscope. Microcrystal-test techniques are divided into two broad categories: aqueous techniques or volatility techniques.
8.5.1
Aqueous Test Technique
Despite considerable variation in testing reagents, the technique for aqueous testing remains unchanged. A reference standard is required and must be run concurrently: • A small sample is placed on a microscope slide and dissolved in one drop of water or one drop of diluted acetic acid (Fig. 8.1). • Place one drop of reagent next to the sample on the slide or place one drop of reagent directly into the test drop (Fig. 8.2). • Mix the two drops (if side by side) (Fig. 8.3). • Place the slide under a microscope and observe crystal formation. – A slide cover is not required.
Fig. 8.1 Small sample placed on a microscope slide and dissolved in one drop of water or one drop of diluted acetic acid.
Fig. 8.2 Place one drop of reagent next to the sample on the slide or place one drop of reagent directly into the test drop.
Fig. 8.3 Mix the two drops (if side by side).
8.6
Aqueous Test Reagents
8.5.2
95
Volatility Test Technique
The volatility technique is used when the test substance is volatile (easily vaporized) or when a solvent is chosen that causes the substance to be volatile. The sample vapors rise and react with a drop of reagent suspended on a slide over the substance. Crystals form in the solution on the cover slide. A reference standard is required and must be run concurrently. • The test sample is placed into the depression of either a clean spot plate or a volatility chamber. • A drop of crystal reagent is placed onto a microscope slide. – The reagent may contain a viscous material to aid in suspension. • The microscope slide is inverted and placed over the depression containing the test sample. Align the reagent drop over the test sample. • The test sample is vaporized. – It may require placing the spot plate onto a warm hot plate. • Allow reagent drop and sample vapors to react. • Place the slide under a microscope and observe crystals. This technique is particularly useful in the detection of volatile poisons containing the aldehyde and ketone functional groups. Controlled substances containing primary and secondary amines have been isolated using this technique. Also, it may have possible applications in the identification of g-hydroxybutyric acid (GHB) and in the detection of explosive residues.
8.5.3
Acid and Anionic Test Technique
This technique combines portions of both the aqueous and volatility techniques. A few crystals of sample are placed in the cavity of a cavity slide, and one drop of alcohol solution (methanol or ethanol) is added. One drop of reagent is added immediately after the alcohol, and a cover slide is placed over the cavity to prevent evaporation. Crystal formation is observed by placing the cavity slide (with cover) directly under a microscope. This method is often used to crystallize steroid hormones and barbiturates, including phenobarbital.
8.6
Aqueous Test Reagents
The protocols for microcrystalline testing, including recommended procedures for the preparation of a vast number of reagents and solvents, are readily available in a variety of scientific publications. However, only a few are used in forensic investigation. The following tests are representative of those commonly used in most forensic laboratories, with only minor variations to reagent preparation.
8.6.1
Gold Chloride Test
Reagent: 3-g gold(III) chloride (AuCl3) + 100-ml water + 0.25-ml concentrated HCl Target: Cocaine
8.6.2
Crystals: Combs and rosettes of needles
Gold Chloride in Phosphoric Acid Test
Reagent 1: 5-g gold(III) chloride (AuCl3) in 100-ml water Reagent 2: Concentrated phosphoric acid (H3PO4) Mix two drops Reagent 1 with one drop Reagent 2. Target: Methamphetamine Target: d-Amphetamine
Crystals: Long needles and long barbs Crystals: Long yellow rods and blades
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8.6.3
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Microcrystal Techniques
Platinum Chloride Test
Reagent: 5-g platinum(IV) chloride (PtCl4) in 100 ml of 1 M hydrochloric acid (HCl) Target: Cocaine
8.6.4
Crystals: Combs of needles
Mercuric Iodide Test
Reagent: 10% hydrochloric acid (HCl) saturated with mercury(II) iodide (HgI2) Target: Heroin
Crystals: Rosettes of dendrites
Note: The test is extremely sensitive, even with highly contaminated samples. Use caution when interpreting results; product crystals are colorless and may be difficult to differentiate from undissolved reagent particles.
8.6.5
Mercuric Chloride Test
Reagent: 5-g mercury(II) chloride (HgCl2) in 100-ml water Target: Methadone
8.6.6
Crystals: Small rosettes of rods
Potassium Permanganate Test
Reagent: 2-g potassium permanganate (KMnO4) + 100-ml water + 0.25-ml phosphoric acid (H3PO4) Target: Phencyclidine (PCP)
Crystals: purple H-shaped plates
Note: The test is extremely sensitive, and the best results are obtained using very dilute samples. It is recommended to use just enough sample to produce a light amorphous precipitate when reagent is added.
8.6.7
Sodium Acetate Test
Reagent: 10-g sodium acetate in 100-ml water Target: Heroin Target: Quinine
8.7
Crystals: Hexagonal plates Crystals: Irregular logs
Critical Considerations
The interpretation of microcrystalline test results requires a great deal of care and attention. The subtle details of structural features are often either lost or hidden by factors influencing crystal formation. The following list contains suggestions designed to minimize the complexities associated with microcrystalline examinations. • The best crystals form very slowly. • Crystals get bigger with time, and larger crystals are more easily interpreted. • Diluted test samples produce better crystals. • Test solutions should never evaporate to dryness. – The solid should separate almost immediately. Extended periods of time promote evaporation and increase the probability that undesired crystalline compounds will form, complicating the results. • Crystals may be affected by changes in ambient temperature and humidity. • Always run reference controls concurrently with samples. • Reagent age can affect crystal formation. The process of microcrystal formation in solution is not fully understood. Nonetheless, there appears to be no shortage of theories that attempt to describe the procedure. Most have narrow applications and have trouble addressing even the
Suggested Reading
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simplest of arguments. The dynamics of crystal formation is really quite simple; crystals will form in any solution when the limit of solute solubility has been reached. But what factors determine a solvent’s capacity to dissolve solute? Alas, this is the real question and, at present, that question is unanswered. There will be no theory that is universally applied to precipitate formation in aqueous-solution chemistry. The complexities of crystal formation will ensure that.
8.8 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14.
Questions Cite two reasons why microcrystal techniques would be used as a confirmatory test. Describe the complete documentation of a microcrystalline-test result. Cite two advantages of microcrystalline techniques. Can you please explain to the jury how a basic microcrystal test is performed? Please explain to the jury how you determined the substance was heroin using the sodium acetate test. How would you test for amphetamine? In your opinion, is this technique in question #6 a confirmatory or a screening examination? Explain. Is it possible for two different substances to produce identical crystals? Explain. Cite three disadvantages of microcrystalline techniques. Discuss two critical factors that need to be considered when evaluating microcrystalline-test results. What group considers microcrystalline tests obsolete? Describe the crystals formed from cocaine and methadone. Discuss an instance when complete documentation of testing results would not be required. Compare and contrast the aqueous technique and the volatility technique.
Suggested Reading California Department of Justice. Technical Procedures Manual for Controlled Substance Analysis; Sacramento, CA., 2006. Chamot, E. M.; Mason, C. W. Handbook of Chemical Microscopy, Volume II: Chemical Methods and Inorganic Qualitative Analysis; McCrone Research Institute: Chicago, 1989, chaps. 11–13. De Forest, P. R.; Gaensslen, R. E.; Lee, H. C. Forensic Science: An Introduction to Criminalistics; McGraw-Hill: New York, 1983, chap. 5. Evans, H. K. Drug and Microcrystal Tests for Forensic Drug identification. Microscope. 1999, 47, p.147. Fulton, C. Modern Microcrystal Tests for Drugs; John Wiley & Sons. New York, 1969. Julian, E. A. Microcrystalline Identification of Drugs of Abuse: The Psychedelic Amphetamines. J. Forensic Sci. 1990, 35, pp. 821–830. Julian, E. A. Microcrystalline Identification of Drugs of Abuse: The White Cross Suite. J. Forensic Sci. 1981, 26, pp. 358–367. Moorehead, W. A Brief Background and Justification for the Continued Use of Microcrystal Tests. CAC News, 2000, 3rd quarter, pp 11–15.
9
Chemical Extractions and Sample Preparation
9.1
Introduction
Solutions are homogeneous mixtures (see Chap. 1) containing two or more substances. The component of a solution present in the greatest amount is called the solvent and the dissolved substances are the solutes. It is possible to have more than one solute in a particular solution; however, it is not possible to have more than one solvent. Solvents have a varying capacity to dissolve particular solutes; for example; sodium chloride (NaCl) will readily dissolve in water, while silver chloride (AgCl) will not. Solubility refers to the maximum amount of solute particles that can be dissolved in a specified volume of solvent at a given temperature. Temperature affects the solubility properties of a solvent and, in general, solubility increases with increasing temperature. A common example of this is illustrated using a simple cup of coffee. Have you ever wondered about the dark sediment that mysteriously appears at the bottom of a cool cup of coffee? Stop blaming your dishwasher and the coffee filters you purchased at the discount store; they are not the culprits. When hot water is added to solid coffee, only specific components are dissolved (extracted) from the coffee grinds into water, that is, flavor, odor, caffeine, etc. The concentration of each component in the resulting solution is dependent on the temperature of water. If the water is very hot, a “strong” cup of coffee results because the water can dissolve a higher concentration of the components (increased solubility). As the coffee cools, the solubility decreases and the components precipitate out as dark sediment in the bottom of the cup. The coffee/water system is an example of solid/liquid extraction because soluble components are transferred from a solid phase (coffee) into a liquid phase (water). Extraction is a general term used to describe a number of chemical techniques that separate the components of a mixture using the solubility properties of various solute/solvent systems. In the context of extraction, solubility often refers only to a solvent’s ability to dissolve a particular solute and not necessarily a quantitative maximum amount. Most extraction techniques are slight variations of three general procedures: solid–liquid extraction, liquid–liquid extraction, or acid–base extraction.
9.2 9.2.1
Techniques Solid–Liquid Extraction
Solid–liquid extraction is most often used to extract a natural component from a solid natural source, such as a dried plant. This technique is found in the isolation procedures of morphine from the opium poppy and cocaine from coca plants. Although the basic concept is used in forensic analysis, a slight modification adds versatility to this technique. This method relies heavily on the selective extraction (transfer) of soluble components from a solid phase into solution. Ideally, a carefully chosen solvent will dissolve only the target compound and no other components. Isolation is accomplished by filtering out the insoluble contaminants and recovering the target compound from the filtrate (solution that passes through filter). This method generally requires a single extraction, and an outline of the general procedure is below. • Identify the components in the solid sample. • Identify the solubility properties of each component. • Select a suitable solvent, ideally one with a high solubility for the target compound and a low solubility for the remaining components. J.I. Khan et al., Basic Principles of Forensic Chemistry, DOI 10.1007/978-1-59745-437-7_9, © Springer Science+Business Media, LLC 2012
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Chemical Extractions and Sample Preparation
• • • •
Add the solvent and agitate. Allow the insoluble components to settle. Filter the solution to remove insoluble contaminants. Analyze the filtrate. The Modification: Alternatively, the solvent can be used to dissolve all components in the sample except the target compound. Isolation is again accomplished using filtration and the target compound is recovered as crystals on the filter paper. This method may require multiple extractions with different solvents, depending on the characteristics of the contaminants. The general procedure is a slight variation of the one described earlier. • Identify the components in the solid sample. • Identify the solubility properties of each component. • Select a suitable solvent, ideally one with a low solubility for the target compound and a high solubility for the remaining components. • Add the solvent and agitate. • Allow the insoluble component to settle. • Filter the solution to remove target compound. – Repeat as required to remove other components. – May require different solvents. • Analyze the crystals on the filter paper.
9.2.2
Liquid–Liquid Extraction
Solubility is a term used to describe solutions containing a solid dissolved in a liquid. It is rarely associated with solutions containing only liquids. If two liquids dissolve in one another, they are said to be miscible and the resulting solution forms a single, continuous layer (i.e., ethanol and water). If two liquids do not dissolve in one another, they are said to be immiscible, and the resulting solution forms two distinct layers. We refer to each layer of an immiscible mixture as a phase. A number of organic solvents are immiscible in water (i.e., oil and water) (Fig. 9.1). Liquid–liquid extractions use carefully chosen immiscible solvent pairs to isolate a target compound in one layer and the impurities in the other. Preferred solvents will readily dissolve the sample, have low boiling points, not react with solutes, and not be either flammable or toxic. Water is commonly one solvent, and any of a number of organic solvents, such as diethyl ether, methylene chloride, or chloroform, is often chosen as the second solvent. The effectiveness of extraction depends on the relative affinity (attraction or preference) of the solute for each solvent. Ideally, one solvent has a high affinity for the target compound and a low affinity for the impurities, while the other’s affinity is low for the target and high for impurities. It is worth noting that affinity is not solubility. A solvent can have a low affinity for a particular solute and still dissolve appreciable amounts (high solubility). Affinity merely refers to a solvent’s ability to retain solute in the presence of another solvent. When performing liquid–liquid extractions, the solid sample is dissolved in one solvent and then mixed with the other. The target compound is extracted (transferred) into the added solvent and
Fig. 9.1 Liquid–liquid extraction utilizes immiscible solvent pairs to isolate target compounds in a single layer of the mixture.
9.2
Techniques
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isolated when the two layers are separated. This process can be repeated to maximize recovery of the target compound. A general procedure is described below. • Identify the components in the solid sample. • Identify the solubility properties of each component. • Select a suitable immiscible solvent pair; ideally, one solvent’s affinity is low for target and high for impurities; the other’s is high for target, and low for impurities. • Dissolve the solid in one solvent, generally the one with low affinity for target and high affinity for impurities. • Add the other solvent (high affinity for target, low affinity for impurities) and mix. • Let the solution stand undisturbed and allow the phases (layers) to form in the immiscible solution. • Separate the layers to isolate the target compound. – Repeat as needed to maximize recovery. • Remove solvent to recover target crystals.
9.2.3
Acid–Base Extraction
Acid–base extractions rely on the fact that the relative solubility of some compounds is affected by pH. This method uses simple acid–base reactions to isolate strong organic acids, weak organic acids, neutral organic compounds, and basic organic substances. When any acid is mixed with any base, the subsequent neutralization reaction (by definition) produces an ionic salt and water. Most ionic salts are soluble in water and insoluble in organic solvents. For example, benzoic acid is an organic acid that is slightly soluble in water, but soluble in a variety of organic solvents. To isolate benzoic acid, it is first dissolved in an organic solvent (i.e., ether) and then mixed with an aqueous weak base (i.e., sodium bicarbonate in water). Water and ether are immiscible. The weak base will selectively react with the benzoic acid in solution. The resulting neutralization reaction will convert benzoic acid into sodium benzoate, a salt that is soluble in water but insoluble in organic solvents. The sodium benzoate will be extracted into the aqueous phase and isolated. Addition of acid to the aqueous phase converts sodium benzoate (soluble salt) back into benzoic acid (insoluble), which can be isolated either by direct precipitation from the aqueous solution or by extraction into the organic layer. Barbiturates and their associated sodium salts are examples of acidic drugs isolated using this method. The following is a general procedure for isolating acidic compounds from basic and neutral compounds. • Dissolve the sample in a suitable organic solvent. – Solvent selection is critical. – Ethers, ketones, chloroform, or methylene chloride are common choices. • Add a suitable aqueous base. – If extracting a strong acid, use a weak base. If extracting a weak acid, use a strong base. In either case, carefully monitor the amount of base added because any excess will require neutralization. – Agitate and allow the mixture to stand undisturbed. – The added base will convert the acid (target compound) in the organic layer into a soluble ionic salt that will be extracted into the aqueous layer. • Remove the aqueous layer (usually the bottom layer) and save. – Repeat base addition to the organic layer two more times to maximize yield. – Combine all aqueous portions. – At this point, you have isolated the soluble salt, not the target compound. • Decrease the pH of the combined aqueous portions to 8. – Concentrated ammonium hydroxide or 2.0 M sodium hydroxide works well. – Adding a base converts the salt back into the original target compound, which is soluble in organic solvents. • Add a suitable organic solvent and agitate. – The target compound is extracted into the organic layer. • Remove the organic layer (usually top) and save. – Repeat organic solvent addition to the aqueous phase two more times to maximize yield. – Combine all organic portions. • Prepare the organic layer for analysis. – May be used in current form. – May require solvent evaporation using a steady stream of air (most organic solvents are volatile).
9.2.4
Neutral Compound Extraction
Controlled substances can be categorized as acidic, basic, or neutral. We have outlined general procedures for the isolation of acidic and basic forms, and the success of these methods is directly linked to the formation of soluble ionic salts. Unfortunately, neutral drugs have no transitional ionic forms. Do not despair; neutral drugs do have a preferential affinity for organic solvents and can be isolated by removing acidic and basic contaminants. Benzodiazepines are an example of controlled substances that are neutral compounds, and the following is a general isolation procedure. • Dissolve the sample in a suitable aqueous acid. – 0.1 M H2SO4 is suggested. – Any basic contaminants will be converted to soluble ionic salts that will remain in the aqueous layer. • Add a suitable organic solvent and agitate. – Ethers, ketones, chloroform, or methylene chloride are common choices. – Basic contaminants remain in the aqueous layer as soluble salts. – Acidic contaminants and the neutral target compound will be extracted into the organic layer.
9.4
Gas Chromatography/Gas Chromatography Mass Spectrometry
103
• Remove the organic layer (usually top) and save. – Repeat organic solvent addition to the aqueous layer two more times to maximize yield. – Combine the three organic layers – Test the aqueous layer and discard. • Add a suitable aqueous base to the combined organic layers. – 0.2 M NaOH is suggested. – The added base will convert acidic contaminants to soluble salts that will be extracted into the aqueous layer. – The neutral target compound is isolated in the organic layer. • Remove the aqueous layer (usually bottom) and discard (test first!). – Repeat aqueous-base addition to combined organic layers two more times to maximize yield. – Discard the aqueous layers. – Save the organic layer. • Prepare the organic layer for analysis. – May be used in current form. – May require solvent evaporation using a steady stream of air (most organic solvents are volatile).
9.3
Sample Preparation
Extraction techniques are used to isolate target compounds for further analysis. In some instances, the sample is ready for immediate use, while in others, it may require further preparation. The level of sample preparation is largely dependent on the chosen method of confirmation.
9.4
Gas Chromatography/Gas Chromatography Mass Spectrometry
Gas chromatography separates the components of a gaseous mixture and introduces them sequentially into a detector. The following standard techniques are often used to prepare samples for gas chromatography (Fig. 9.2).
Fig. 9.2 Sample preparation for gas-chromatography mass-spectrometry (GCMS) analysis.
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9.5
9
Chemical Extractions and Sample Preparation
Dry-Extraction Gas-Chromatography Modification
This method is used for raw samples and samples purified using thin-layer chromatography. • Approximately 1 mg of sample is placed into a sample container using: – 2-ml autosampler vial or – 3 × 50-mm culture tube • Approximately 1 ml of organic solvent is added to the sample container. – The organic solvent used will depend on the solubility properties of the target compound. – A 1-mg/ml sample concentration is an acceptable analytical standard. (a) The actual concentration of components will be proportionally